Method for the biocatalytic cyclization of terpenes and cyclase mutants employable therein

ABSTRACT

The present invention relates to novel mutants with cyclase activity and use thereof in a method for biocatalytic cyclization of terpenes, such as in particular for the production of isopulegol by cyclization of citronellal; a method for the preparation of menthol and methods for the biocatalytic conversion of further compounds with structural motifs similar to terpene.

RELATED APPLICATIONS

This application claims the benefit under 35 U.S.C. §119(e) of U.S. Provisional Application 61/414,434, filed Nov. 17, 2010; U.S. Provisional Application 61/499,228, filed Jun. 21, 2011; and U.S. Provisional Application 61/540,028, filed Sep. 28, 2011.

SUBMISSION OF SEQUENCE LISTING

The Sequence Listing associated with this application is filed in electronic format via EFS-Web and hereby incorporated by reference into the specification in its entirety. The name of the text file containing the Sequence Listing is Second_Revised_Sequence_List_(—)13111_(—)00194_US. The size of the text file is 1,427 KB, and the text file was created on May 10, 2012.

The present invention relates to novel methods for cyclizing terpenes using cyclases and to novel mutants with cyclase activity and use thereof in a method for biocatalytic cyclization of terpenes, such as in particular for the production of isopulegol by cyclization of citronellal; a method for the preparation of menthol and methods for the biocatalytic conversion of further compounds with structural motifs similar to terpene.

BACKGROUND OF THE INVENTION

Isopulegol of formula (II) (2-isopropenyl-5-methyl-cyclohexanol) is a terpene that is used as an aroma compound, to generate “flower notes”. Moreover, it is an intermediate in the synthesis of menthol from citral.

Isopulegol isomers occur in nature in a large number of essential oils. As isopulegol is formed relatively easily from citronellal, the compound of formula (I) (3,7-dimethyloct-6-en-1-al), it often occurs accompanying citronellal or is formed during extraction of the essential oil. Isopulegol, which is produced industrially from (+)-citronellal, is as a rule a mixture of different isomers with a high proportion of (−)-isopulegol.

The industrial production of isopulegol is mainly carried out by the chemical cyclization of (+)-citronellal. Originally 80-85% pure raw material obtained from citronella oil was used. Since the 1990s this has increasingly been replaced with the optically purer (+)-citronellal (97.5%) from the so-called Takasago process. Here, geranyldiethyldiamine is isomerized asymmetrically to (+)-citronellal using an Rh-BINAP-complex catalyst (Rh-complex with 2,2′-bis-(diphenylphosphino)-1,1′-binaphthyl).

The chemical synthesis of isopulegol starting from citronellal has been described many times. (+)-Citronellal can be cyclized using a copper-chromium catalyst, zinc bromide, alkylaluminum chloride, a rhodium complex, a solid acid-base catalyst, zeolite or silica gel. In recent times the silica gel method has increasingly been superseded by the method with zinc bromide, as the latter has higher selectivity.

The cyclization of terpenes with the aid of special cyclases is generally known. For example, in nature squalene is cyclized by a squalene-hopene cyclase (SHC) to the pentacyclic hopene.

The gene and protein sequences of squalene-hopene cyclase derived from the bacterium Zymomonas mobilia (Zm-SHC) are known (Genpept Accession No AAV90172 2004 and Nat Biotechnol 2005, 23:63-68, cf. SEQ ID NO: 1 and 2).

In international application PCT/EP2010/057696 (WO2010139719 A2), to the complete disclosure of which reference is expressly made herein, polypeptides are proposed as biocatalysts for the cyclization homofarnesol to ambroxan.

The biosynthesis of numerous monoterpenes in the corresponding production organisms has already been elucidated. Frequently this involves cyclization of linear precursor molecules by highly specific biocatalysts. The precursors are generally esters of linear terpene alcohols and diphosphoric acid. One typical example of such a precursor is geranyl pyrophosphate. The pyrophosphate group is eliminated from the molecule enzymatically, and is subsequently hydrolyzed into two phosphate ions. On the other side, a carbocation is formed, which is then able to undergo further intramolecular reaction and which recombines to form a cyclic monoterpene, with elimination of a proton, for example (Curr. Opin. Chem. Biol. 2009, 13: 180-188).

A problem to be solved by the present invention, furthermore, was to find an alternative to the known chemical cyclization methods for terpenes, allowing terpene compounds to be cyclized by means of enzymatic catalysis, such as the linear citronellal to be cyclized to isopulegol, for example.

The problem to be solved by the present invention was furthermore to provide novel biocatalysts that can be used for the cyclization of terpenes, for example of citronellal with formation of isopulegol.

SUMMARY OF THE INVENTION

The above first problem is solved by a method of production of isopulegol of general formula (I)

comprising one reaction step, wherein citronellal of general formula (II)

is cyclized biocatalytically to the corresponding isopulegol of formula (I) by means of an enzyme having the activity of citronellal-isopulegol cyclase.

The above second problem could, surprisingly, be solved by providing mutants of wild-type enzymes, such as Zm-SHC-1 (SEQ ID NO:2). In particular it was in fact found that through targeted introduction of mutations in at least one highly conserved sequence position in said cyclases, in particular squalene-hopene cyclases (cf. alignment of SEQ ID NOs. 2 to 326, below) the enzymatic activity can be influenced in the desired manner.

DESCRIPTION OF THE FIGURES

FIG. 1 a shows the wad-type amino acid sequence (SEQ ID NO: 2) of squalene-hopene cyclase 1 from Zymomonas mobilis (Zm-SHC-1). Position 486 of saturation mutagenesis is marked.

FIG. 1 b shows the wild-type nucleic acid sequence (SEQ ID NO: 1) of Zm-SHC-1. Positions 1456-1458 of saturation mutagenesis are marked.

FIG. 2 shows the turnover of the SHC_(—)1 WT protein compared with the F486A mutant as a function of time with 10 mM R(+)- and S(−)-citronellal as substrate. The percentage distribution of substrate and isopulegol product isomers after incubation for various times at 30° C. is shown in each case. Citronellal (diamonds), isopulegol I (squares), isopulegol II (triangles) and isopulegol III (crosses).

FIG. 3 shows the turnover of the various mutants of Zm-SHC-1 compared with the wild type (wt) and the control without enzyme (K) with 10 mM citronellal racemate as substrate. The percentage distribution of substrate and isopulegol product isomers after incubation overnight at 30° C. is shown in each case.

FIG. 4 shows the turnover of the various Zm-SHC-1 mutants compared with the wild type (wt) and the control without enzyme (K) with 25 mM squalene as substrate in the presence of 1% Triton. The percentage distribution of squalene and hopene after incubation for 70 h at 30° C. is shown in each case.

FIGS. 5 to 7 show the reaction of in each case 20 mM substrate after incubation overnight with the mutants Ap-SHC: F481C, Bj-SHC: F447C, Sc-SHC: F449C, Zm SHC-2: F438C and Zm SHC-1 compared with the control; the substrates were citronellal racemate in FIG. 5, R(+)-citronellal in FIG. 6 and S(−)-citronellal in FIG. 7.

DETAILED DESCRIPTION OF THE INVENTION A. General Definitions

“Cyclases” in the sense of the present invention are generally enzymes or enzyme mutants, which in particular display the activity of a citronellal-isopulegol cyclase. Intramolecular transferases from the isomerase subclass are suitable as enzymes with the activity of a citronellal-isopulegol cyclase; i.e. proteins with the EC number EC 5.4. (Enzyme code according to Eur. J. Biochem. 1999, 264, 610-650). In particular they are representatives of EC 5.4.99.17.

Suitable enzymes with the activity of a citronellal-isopulegol cyclase are in particular those cyclases that also bring about the cyclization of homofarnesol to ambroxan or of squalene to hopene (hence sometimes also designated “SHC”: squalene hopene cyclase) and which are described in detail in international application PCT/EP2010/057696, to which reference is expressly made here. In particular, cyclases according to the invention are those that are derived by mutation of SHCs.

On the basis of the reversibility of enzymatic reactions, the present invention relates to the enzymatic reactions described herein in both directions of reaction.

“Functional mutants” of a “cyclase” include the “functional equivalents” of such enzymes defined below.

The term “biocatalytic process” refers to any process carried out in the presence of catalytic activity of a “cyclase” according to the invention or of an enzyme with “cyclase activity”, i.e. processes in the presence of raw, or purified, dissolved, dispersed or immobilized enzyme, or in the presence of whole microbial cells, which have or express such enzyme activity. Biocatalytic processes therefore include both enzymatic and microbial processes.

The term “stereospecific” means that one of several possible stereoisomers of a compound produced according to the invention is produced with at least one asymmetry center by the action of an enzyme according to the invention in high “enantiomeric excess” or high “enantiomeric purity”, for example at least 90% ee, in particular at least 95% ee, or at least 98% ee, or at least 99% ee. The ee % value is calculated from the following formula:

ee%=[X _(A) −X _(B) ]/[X _(A) +X _(B)]*100,

in which X_(A) and X_(B) stand for the mole fraction of enantiomers A and B respectively.

“First sphere residues” and “second sphere residues” are amino acid residues which, based on structural analyses of the protein, are assigned a special proximity to the reactive center of the cyclase. The criterion for the first sphere is the distance from the ligand 2-azasqualene, which is given in a published x-ray structure (pdb: 1 ump). These residues were determined automatically with a computer program (ligin.weizmann.ac.il/cgi-bin/lpccsu/LpcCsu.cgi; Sobolev V, Sorokine A, Prilusky J, Abola E E, Edelman M. Automated analysis of interatomic contacts in proteins. Bioinformatics 1999; 15(4):327-332.). This program assumes that two molecules are in contact with each other when the distance between their atoms corresponds to the sum of their van der Waals radii±1 Å. The second sphere includes all amino acids that are located in a radius of 5 Å to each residue of the first sphere. Such residues therefore appear to be especially suitable for undertaking directed mutation, for further targeted modification of the enzyme activity.

“Cyclase activity”, determined with a “reference substrate under standard conditions”, is e.g. an enzyme activity that describes the formation of a cyclic product from a noncyclic substrate. Standard conditions are e.g. substrate concentrations from 10 mM to 0.2 M, in particular 15 to 100 mM, for example about 20 to 25 mM; at pH 4 to 8, and at temperatures of e.g. 15 to 30 or 20 to 25° C. It can be determined with recombinant cyclase-expressing cells, lysed cyclase-expressing cells, fractions thereof or enriched or purified cyclase enzyme. In particular the reference substrate is a citronellal of formula (II); in particular R(+)-citronellal, or a citronellal racemate, in a concentration from 15 to 100 mM or about 20 to 25 mM, at 20 to 25° C. and pH 4-6, such as 4.5; as is also described in more detail in the examples.

An “F486-analog” position corresponds to position F486 according to SEQ ID NO:2 from the functional standpoint and can be determined by sequence alignment of SHCs from organisms other than Zymomonas mobilis as explained herein. For example the F486-analog position of SEQ ID NO:3 is position F449 and of SEQ ID NO:4 position F481 and of SEQ ID NO:5 position F447 and of SEQ ID NO:6 position F438. Corresponding analogies apply to the other sequence positions described concretely for SEQ ID NO: 2 herein, such as the so-called “first sphere residues” and “second sphere residues” or of the DXDD motif and their analogous positions in SEQ ID NO:3 to 326).

“Terpenes” are hydrocarbons that are made up of isoprene units (C5 units), in particular noncyclic terpenes, for example squalene, the carbon number of which is divisible by 5.

“Terpenoids” are substances that are derived from terpenes, in particular noncyclic terpenes, e.g. by additional insertion of carbon atoms and/or heteroatoms, for example citronellal.

“Terpene-like” compounds for the purposes of the present invention comprise in particular hose compounds which fall within the general structural formula (IV) as defined below.

Generally encompassed in accordance with the invention are all isomeric forms of the compounds described herein, such as constitutional isomers and more particularly stereoisomers and mixtures thereof, such as optical isomers or geometric isomers, such as E- and Z-isomers, and also combinations thereof. Where there are two or more centers of asymmetry in a molecule, the invention encompasses all combinations of different conformations of these centers of asymmetry, such as pairs of enantiomers, for example.

“Menthol” encompasses all stereoisomeric forms such as (+)-menthol, (+)-isomenthol, (+)-neomenthol, (+)-neoisomentol, (−)-menthol, (−)-isomenthol, (−)-neomenthol, (−)-neoiso-menthol and any desired mixtures thereof.

Citronellal of formula (II) is commercially available both as R(+)-citronellal of formula (R-II) and as S(−)-citronellal of formula (S-II) and as racemate of formula (II).

Isopulegol of formula (I)

has in positions 1, 3 and 6 in each case an optically active center, so that in principle 4 different diastereomers with in each case 2 enantiomers, thus altogether 8 stereoisomers, are conceivable, starting from the racemate of citronellal of formula (I).

Isopulegol is also called isopulegol I, neo-isopulegol is also called Isopulegol II; iso-isopulegol is also called isopulegol III; epi-isopulegol or neo-iso-isopulegol is also called isopulegol IV.

Unless indicated otherwise, the general chemical definitions that apply herein are as follows:

Alkyl and also all alkyl moieties in radicals derived therefrom, such as hydroxyalkyl, for example: saturated, straight-chain or branched hydrocarbon radicals having 1 to 4, 1 to 6, 1 to 8 or 1 to 10 carbon atoms, e.g.

-   -   C₁-C₆-alkyl: such as methyl, ethyl, propyl, 1-methylethyl,         butyl, 1-methylpropyl, 2-methyl-propyl and 1,1-dimethylethyl as         exemplary representatives of C₁-C₄-alkyl; and also pentyl,         1-methylbutyl, 2-methylbutyl, 3-methylbutyl, 2,2-dimethylpropyl,         1-ethylpropyl, hexyl, 1,1-dimethylpropyl, 1,2-dimethylpropyl,         1-methylpentyl, 2-methylpentyl, 3-methylpentyl, 4-methylpentyl,         1,1-dimethylbutyl, 1,2-dimethylbutyl, 1,3-dimethylbutyl,         2,2-dimethylbutyl, 2,3-dimethylbutyl, 3,3-dimethylbutyl,         1-ethylbutyl, 2-ethylbutyl, 1,1,2-trimethylpropyl,         1,2,2-tri-methylpropyl, 1-ethyl-1-methylpropyl and         1-ethyl-2-methylpropyl,     -   Hydroxy-C₁-C₆-alkyl, comprising hydroxy-C₁-C₄-alkyl, such as         e.g. hydroxymethyl, 1- or 2-hydroxyethyl, 1-, 2- or         3-hydroxypropyl, 1-hydroxymethylethyl, 1-, 2-, 3- or         4-hydroxybutyl, 1-hydroxymethylpropyl and 2-hydroxymethylpropyl.

Alkenyl stands for mono- or polyunsaturated, more particularly monounsaturated, straight-chain or branched hydrocarbon radicals having 2 to 4, 2 to 6, 2 to 8, 2 to 10 or 2 to 20 carbon atoms and one double bond in any desired position, e.g. C₂-C₆-alkenyl such as ethenyl, 1-propenyl, 2-propenyl, 1-methylethenyl, 1-butenyl, 2-butenyl, 3-butenyl, 1-methyl-1-propenyl, 2-methyl-1-propenyl, 1-methyl-2-propenyl, 2-methyl-2-propenyl, 1-pentenyl, 2-pentenyl, 3-pentenyl, 4-pentenyl, 1-methyl-1-butenyl, 2-methyl-1-butenyl, 3-methyl-1-butenyl, 1-methyl-2-butenyl, 2-methyl-2-butenyl, 3-methyl-2-butenyl, 1-methyl-3-butenyl, 2-methyl-3-butenyl, 3-methyl-3-butenyl, 1,1-dimethyl-2-propenyl, 1,2-dimethyl-1-propenyl, 1,2-dimethyl-2-propenyl, 1-ethyl-1-propenyl, 1-ethyl-2-propenyl, 1-hexenyl, 2-hexenyl, 3-hexenyl, 4-hexenyl, 5-hexenyl, 1-methyl-1-pentenyl, 2-methyl-1-pentenyl, 3-methyl-1-pentenyl, 4-methyl-1-pentenyl, 1-methyl-2-pentenyl, 2-methyl-2-pentenyl, 3-methyl-2-pentenyl, 4-methyl-2-pentenyl, 1-methyl-3-pentenyl, 2-ethyl-3-pentenyl, 3-methyl-3-pentenyl, 4-methyl-3-pentenyl, 1-methyl-4-pentenyl, 2-methyl-4-pentenyl, 3-methyl-4-pentenyl, 4-methyl-4-pentenyl, 1,1-dimethyl-2-butenyl, 1,1-dimethyl-3-butenyl, 1,2-dimethyl-1-butenyl, 1,2-diethyl-2-butenyl, 1,2-dimethyl-3-butenyl, 1,3-diethyl-1-butenyl, 1,3-dimethyl-2-butenyl, 1,3-dimethyl-3-butenyl, 2,2-diethyl-3-butenyl, 2,3-dimethyl-1-butenyl, 2,3-diethyl-2-butenyl, 2,3-dimethyl-3-butenyl, 3,3-dimethyl-1-butenyl, 3,3-dimethyl-2-butenyl, 1-ethyl-1-butenyl, 1-ethyl-2-butenyl, 1-ethyl-3-butenyl, 2-ethyl-1-butenyl, 2-ethyl-2-butenyl, 2-ethyl-3-butenyl, 1,1,2-triethyl-2-propenyl, 1-ethyl-1-methyl-2-propenyl, 1-ethyl-2-methyl-1-propenyl and 1-ethyl-2-methyl-2-propenyl.

“Oxo”, for example, is a radical which together with the C atom to which it is bonded forms a keto group (C═O).

“Methylene” (═CH₂), for example, is a radical which together with the C atom to which it is bonded forms a vinyl radical (—CH═CH₂).

B. Special Embodiments of the Invention

The present invention relates in particular to the following special embodiments:

-   1. Enzyme mutant with cyclase activity, selected from mutants of a     wild-type enzyme, which comprises an amino acid sequence, selected     from SEQ ID NO: 2 to 326 or a partial sequence thereof; wherein the     mutant catalyzes at least the cyclization of at least one     citronellal isomer (or a mixture of isomers, for example racemate)     according to the above definition to at least one isopulegol isomer     (or to a pair of diastereomers I to IV, for example I and/or II)     according to the above definition, wherein the partial sequence or     short form of the cyclase comprises e.g. at least 50, 100, 150, 200,     250, 300, 350, 400, 450, 500, 550, 600, 650 or 700 continuous amino     acid residues of one of these sequences, and is accessible e.g. by     N- and/or C-terminal shortening of the concrete sequences. -   2. Enzyme mutant according to embodiment 1, comprising     -   a) a mutation in position F486 of SEQ ID NO: 2 or     -   b) a mutation in a sequence selected from SEQ ID NO: 3 to 326,         wherein the mutated position corresponds to position F486 of SEQ         ID NO: 2 (i.e. is an “F486-analog” position);     -   wherein at least the cyclization of at least one citronellal         isomer to at least one isopulegol isomer is made possible by the         mutation (i.e. the corresponding original or wild-type protein         did not catalyze this reaction) or is modified (i.e. the         corresponding original or wild-type protein catalyzed this         reaction, but e.g. at lower product yield, turnover rate and/or         stereospecificity). Moreover, the partial sequence or short form         of the cyclase also has this cyclase-typical mutation in a         position corresponding to F486 from SEQ ID NO: 2. For example,         an N-terminally shortened version of the cyclase according to         SEQ ID NO: 2 is an example of said short version. This is         characterized by the following N-terminus:         (M)KIFGAEKTSYKPASDTIIGTDTLKRPN . . . wherein the N-terminal K         corresponds to position 16 of SEQ ID NO:2. -   3. Enzyme mutant according to one of the preceding embodiments in     which up to 25% or up to 20, 15, 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of     the amino acid residues, for example 1 to 30, 2 to 25, 3 to 20 or 4     to 15 or 5 to 10 of the amino acid residues, are in each case     altered relative to the unmutated wild-type sequence according to     SEQ ID NO: 2 to 326, by deletion, insertion, substitution, addition,     inversion or a combination thereof. -   4. Enzyme mutant according to one of the preceding embodiments, in     which the mutation in position F486 of SEQ ID NO:2 or in a position     corresponding to this position in one of the sequences according to     SEQ ID NO: 3 to 326, is a substitution selected from F486N, F486Q,     F486L, F486M, F486E, F486G, F486S, F486V, F486T, F486C, F4861 and     F486A or optionally selected from F48611, F486Y, F486W and F486D. -   5. Enzyme mutant according to one of the preceding embodiments, in     which additionally (or alternatively, but in particular     additionally) at least one, for example 1, 2, 3, 4, 5, 6, 7, or 8,     mutations in one of the positions W374, D437, D440, F428, W555,     Y561, Y702, Y705 (the so-called “first sphere residues”) of SEQ ID     NO: 2 or in at least one corresponding position selected from these     positions, is present in one of the sequences according to SEQ ID     NO: 3 to 326. -   6. Enzyme mutant according to one of the preceding embodiments, in     which there is no mutation in position D437 and/or D439 and/or D440     of SEQ ID NO: 2 (DXDD motif) or the respective corresponding     position in one of the sequences according to SEQ ID NO: 3 to 326. -   7. Enzyme mutant according to one of the preceding embodiments, in     which there is no mutation in position Y702 of SEQ ID NO: 2 or in     the corresponding position in one of the sequences according to SEQ     ID NO: 3 to 326, or if a mutation is present, this is a substitution     Y702F or optionally Y702E or Y702D or corresponding substitution. -   8. Enzyme mutant according to one of the preceding embodiments,     which optionally is further mutated in at least one, for example 1     to 15, 1 to 10 or 1 to 5, such as 1, 2, 3 or 4, of positions P229,     D439, D508, E601, G553, G556, N432, P436, P499, R224, S371, T376,     T563, W414 or W624 (the so-called “second sphere residues”) of SEQ     ID NO: 2 or in at least one corresponding position selected from     these positions, in one of the sequences according to SEQ ID NO: 3     to 326; and optionally a further mutation in position E429. L700 and     R554 of SEQ ID NO: 2 or the analogous positions of SEQ ID NO: 3 to     326. -   P 9. Enzyme mutant according to one of the preceding embodiments,     selected from     -   a) the single mutants         -   F486X with X═N, Q, L, M, E, G, S, V, T, C, I or A according             to SEQ ID NO: 2 or a short version thereof;         -   Y702X with X═F, A, C S according to SEQ ID NO: 2 or a short             version thereof;         -   Y561X with X=A or S according to SEQ ID NO: 2 or a short             version thereof;         -   wherein the short version comprises e.g. the following             N-terminal sequence:

(M)KIFGAEKTSYKPASDTIIGTDTLKRPN......

-   -   b) the multiple mutants F486A/Y702A, F486A Y561A or F486A Y705A         according to SEQ ID NO: 2     -   c) the mutants corresponding to a) or b), derived from one of         SEQ ID NO: 3 to 325,

-   10. Enzyme mutant according to one of the preceding embodiments,     which comprises at least 50%, for example 50 to 100% or more than     100%, for example >100 to 1000%, in each case determined under     standard conditions using a reference substrate that displays     citronellakisopulegol cyclase activity of an enzyme, which has an     amino acid sequence according to SEQ ID NO: 2 from position 1 to     725, 2 to 725 or 16 to 725, optionally extended N-terminally with a     methionine residue.

-   11. Enzyme mutant according to embodiment 10, wherein the     citronellal-isopulegol cyclase activity is determined under standard     conditions using a citronellal, for example the racemate or the R(+)     form, as reference substrate.

-   12. Enzyme mutant according to one of the preceding embodiments,     wherein the mutation takes place in an enzyme, and comprises an     amino acid sequence according to SEQ ID NO: 2 from position 1 to     725, 2 to 725 or 16 to 725, optionally extended N-terminally with a     methionine residue.

-   13, Nucleic acid sequence coding for a mutant according to one of     the preceding embodiments.

-   14. Expression cassette, comprising a nucleic sequence according to     embodiment 13.

-   15. Recombinant vector, comprising, under the control of at least     one regulatory element, at least one nucleic acid sequence according     to embodiment 13 or at least one expression cassette according to     embodiment 14.

-   16. Recombinant microorganism, comprising at east one nucleic acid     sequence according to embodiment 13 or at least one expression     cassette according to embodiment 14 or at least one vector according     to embodiment 15.

-   17. Biocatalytic process for producing isopulegol of general formula     (I)

-   -   wherein citronellal of general formula (II)

-   -   is cyclized to isopulegol of formula (I) by means of an enzyme         of EC class EC 5.4.99, in particular of EC class EC 5.4.99.17,         or in the presence of a microorganism expressing this enzyme.

-   18. Biocatalytic process for producing isopulegol of general form a     (I)

-   -   wherein citronellal of general formula (II)

-   -   is cyclized to isopulegol of formula (I) by means of an enzyme         mutant according to one of embodiments 1 to 12, or in the         presence of a microorganism expressing this enzyme mutant         according to embodiment 16.

-   19. A method of production of menthol formula III

-   -   by     -   a) cyclizing citronellal to isopulegol by a method according to         claim 17 or 18, and     -   b) catalytically hydrogenating isopulegol to menthol,

-   20. The method according to claim 19, where the hydrogenation takes     place in the presence of hydrogen and a catalyst comprising     -   30% to 70% by weight of oxygen-containing compounds of nickel,         calculated as NiO,     -   15% to 45% by weight of oxygen-containing compounds of         zirconium, calculated as ZrO₂,     -   5% to 30% by weight of oxygen-containing compounds of copper,         calculated as CuO, and     -   0.1% to 10% by weight of oxygen-containing compounds of         molybdenum, calculated as MoO₃,     -   the % by weight figures being based on the dry, unreduced         catalyst.

-   21. A method for enzymatic or biocatalytic conversions of compounds     of general formula IV

-   -   in which     -   “a”, “b”, “c” and “d”, in each case independently of one         another, represent a single or double C—C bond, with the proviso         that cumulative double bonds are excluded; and with the         following provisos:     -   R₁ possesses the following definitions:         -   (1) when “a” is a double bond:             -   R₁ is selected from                 -   oxo(═O), or                 -   CH—(CH₂)_(n)—Z.                 -    in which n is 0, 1 or 2 and                 -    Z is OH, CHO, C(O)alkyl, such as C(O)C₁-C₄-alkyl,                     in particular C(O)—CH₃ or C(O)—-CH₂CH₃; COOH,                     C(CH₂)—CH═CH₂;                 -    C(OH)(CH₃)—CH═CH₂; C(CH₃)═CH—CH═CH₂; or a radical                     of the formula C(CH₃)═CH—CH₂Y                 -    in which                 -    Y is OH, CH₂OH, COOH, CH₂C(O)CH₃; or         -   (2) when “a” is a single bond:             -   R₁ is selected from                 -   CH₃; CHO; CH₂CH₂OH; CH═CH₂; CH₂C(O)OH; CH₂CHO or                     C₃H₆CH(CH₃)CHO;         -   wherein, when “a” is a double bond, it has E or Z             configuration;     -   R₂ and R₃ possess the following definitions:         -   (1) when “a” and “b” are each a single bond:             -   R₂ and R₃ independently of one another are H, alkyl,                 such as C₁-C₄-alkyl or OH, or R₂ and R₃ together are a                 methylene (═CH₂) or oxo (═O) group; or         -   (2) when “a” or “b” is a double bond, one of the radicals R₂             and R₃ is absent and the other of the two radicals is H,             C₁-C₄-alkyl, in particular methyl, or OH;     -   R₄ is H or hydroxy-C₁-C₄-alkyl, in particular Hydroxymethyl;     -   R₅ and R₆ possess the following definitions:         -   (1) when “c” is a single bond:             -   R₅ and R₆ are each H, or R₅ and R₆ together are an oxo                 (═O) group; or         -   (2) when “c” is a double bond, one of the radicals R₅ and R₆             is absent and the other of the two radicals is H;     -   R₇, R₈ and R₉ possess the following definitions:         -   (1) when “d” is a single bond:             -   two of the radicals R₇, R₈ and R₉ in each case                 independently of one another are H or alkyl, such as                 C₁-C₄-alkyl, in particular methyl or ethyl, and the                 other of the radicals is OH; or             -   (2) when “d” is a double bond, one of the radicals R₇,                 R₈ and R₉ is absent and the other of the two radicals in                 each case independently of one another are H or alkyl,                 such as C₁-C₄-alkyl, in particular methyl or ethyl;     -   R₁₀ is H or hydroxy-C₁-C₆-alkyl, such as hydroxy-C₁-C₄-alkyl, or         mono- or polyunsaturated C₂-C₆-alkenyl, such as, in particular,         H or CH═CH—C(CH₃)═CH₂     -   where a compound of the formula IV in stereoisomerically pure         form, or a stereoisomer mixture thereof, is reacted using an         enzyme of class EC 5.4.99, in particular of class EC 5.4.99.17,         or an enzyme mutant according to one of embodiments 1 to 12 or         in the presence of a microorganism according to embodiment 16         expressing these enzymes or enzyme mutants.

-   22. The method according to embodiment 21, in which a compound is     converted which is selected from compounds of the formula IVa

-   -   in which R₁ possesses the definitions indicated above and in         particular is the radical CH—(CH₂)_(n)—Z     -   in which         -   n=0 and Z═CHO, or COON; or         -   n=1 and Z═OH; or         -   n=2 and Z═C(O)CH₃; COOH, C(CH₂)—CH═CH₂; C(CH₃)═CH—CH═CH₂;             -   or is a radical of the formula C(CH₃)═CH—CH₂Y             -   in which Y is OH, CH₇OH, COOH, or CH₂C(O)CH₃;     -   and “a” optionally has E or Z configuration;     -   or of the formula IVb

-   -   in which R₁ possesses the definitions indicated above and in         particular is CH₂CHO;     -   or of the formula IVc

-   -   in which     -   R₁ possesses the definitions indicated above, and in particular         is CH—CHO; and one of the radicals R₇ and R₈ is H and the other         is C₁-C₄-alkyl, where in particular R₇ is ethyl and the double         bonds “a” and “d” have Z configuration.

-   23. The method according to one of embodiments 20 to 22, in which     the compound of the formula IV is selected from citronellal; citral;     farnesol; homofarnesol; homofarnesol derivatives, such as     homofarnesylic acid; geranylacetone, melonal; nonadienal; and     trimethyldecatetraene.

-   24. Use of an enzyme from EC class EC 5.4.99, in particular from EC     class EC 5.4.99.17 for the cyclization of terpenes and/or     terpenoids, in particular for the conversion of citronellal to     isopulegol.

-   25. Use of an enzyme mutant according to one of embodiments 1 to 12,     a nucleic acid according to embodiment 13, an expression construct     according to embodiment 14, a recombinant vector according to     embodiment 15 or a recombinant microorganism according to embodiment     1 for the cyclization terpenes and/or terpenoids, and for the     conversion of compounds of the general formula IV according to the     definition in one of the embodiments 20 to 23.

-   25. Use according to embodiment 25 for the conversion of citronellal     to isopulegol; or for the conversion of squalene to hopene.

-   26. A method of production of isopulegol of general formula (I)

-   -   comprising one reaction step,     -   wherein citronellal of general formula (II)

is cyclized biocatalytically to the corresponding isopulegol of formula (I) by means of an enzyme having the activity of a citronellal-isopulegol cyclase.

-   27. The method according to embodiment 26, wherein the enzyme     possesses a polypeptide sequence which either     -   a) is SEQ ID NO: 2, or     -   b) in which up to 25%, such as, for example, up to 20, 15, 10,         9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues are         altered relative to SEQ ID NO: 2 by deletion, insertion,         substitution or a combination thereof, and which still has at         least 50%, such as, for example, at least 60, 65, 70, 75, 80,         85, 90 or 95%, of the enzymatic activity of SEQ ID NO: 2. -   28. The method according to embodiment 26 or 27, wherein the enzyme     is encoded by a nucleic acid sequence according to SEQ ID NO: 1 or a     functional equivalent thereof. -   29. The method according to one of embodiments 26 to 28, wherein the     enzyme is encoded by a nucleic acid sequence according to SEQ ID NO:     1 or a functional equivalent thereof, the nucleic acid sequence     being part of a gene construct or vector. -   30. The method according to one of embodiments 26 to 29, wherein the     enzyme is encoded by a nucleic acid sequence according to SEQ ID NO:     1 or a functional equivalent thereof, the nucleic acid sequence     being part of a gene construct or vector which are present in a host     cell. -   31. The method according to one of embodiments 26 to 30, wherein the     enzyme is present in a form selected from the group consisting of:     -   a) free, optionally purified or partly purified polypeptide         having the activity of a citronellal-isopulegol cyclase;     -   b) immobilized polypeptide having the activity of a         citronellal-isopulegol cyclase;     -   c) polypeptide according to a) or b) which is isolated from         cells;     -   d) whole cell, optionally resting or digested cells, comprising         at least one polypeptide having the activity of a         citronellal-isopulegol cyclase;     -   e) cell lysate or cell homogenate of the cells described under         d). -   32. The method according to embodiment 31, wherein the cells are     microorganisms, preferably transgenic microorganisms expressing at     least one heterologous nucleic acid molecule coding for a     polypeptide having the activity of a citronellal-isopulegol cyclase. -   33. The method according to one of embodiments 26 to 32, wherein the     production of isopulegol takes place in one-phase aqueous systems or     in two-phase systems. -   34. The method according to one of embodiments 26 to 33, in which     the reaction of citronellal to isopulegol takes place at a     temperature in the range from 20 to 40° C. and/or at a pH in the     range from 4 to 8. -   35. The method according to one of embodiments 26 to 34, wherein the     enzyme having the activity of a citronellal-isopulegol cyclase is     encoded by a gene which has been isolated from a microorganism     selected from the group of microorganisms consisting of Zymomonas     mobilis, Methylococcus capsulatus, Rhodopseudomonas palustris,     Bradyrhizobium japonicum, Frankia spec. and Streptomyces coelicolor,     in particular Zymomonas mobilis. -   36. The method according to one of embodiments 26 to 35, wherein the     enzyme having the activity of a citronellal-isopulegol cyclase has     been produced by a microorganism which overproduces the enzyme     having the activity of a citronellal-isopulegol cyclase and which     has been selected from the group of microorganisms consisting of the     genera Escherichia, Corynebacterium, Ralstonia, Clostridium,     Pseudomonas, Bacillus, Zymomonas, Rhodobacter, Streptomyces,     Burkholderia, Lactobacillus and Lactococcus. -   37. The method according to one of embodiments 26 to 36, wherein the     enzyme having the activity of a citronellal-isopulegol cyclase has     been produced by transgenic microorganisms of the species     Escherichia coli, Pseudomonas putida, Burkholderia glumae,     Corynebacterium glutamicum, Saccharomyces cerevisiae. Pichia     pastoris, Streptomyces lividans, Streptomyces coelicolor, Bacillus     subtilis or Zymomonas mobilis which overproduce the enzyme having     the activity of a citronellal-isopulegol cyclase. -   38. Use of an enzyme having the activity of a citronellal-isopulegol     cyclase for the biocatalytic conversion of citronellal to     isopulegol. -   39. Use according to embodiment 38, wherein the enzyme possesses a     polypeptide sequence which either     -   a) is SEQ ID NO: 2, or     -   b) in which up to 25%, such as, for example, up to 20, 15, 10,         9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues are         altered relative to SEQ ID NO: 2 by deletion, insertion,         substitution or a combination thereof, and which still has at         least 50%, such as, for example, at least 60, 65, 70, 75, 80,         85, 90 or 95%, of the enzymatic activity of SEQ ID NO: 2. -   40. Use according to embodiment 38 or 39, wherein the enzyme is     encoded by a nucleic acid sequence according to SEQ ID NO: 1 or a     functional equivalent thereof. -   41. Use of a gene construct or vector comprising a nucleic acid     sequence according to SEQ ID NO: 1 or a functional equivalent     thereof, which encode a polypeptide having the activity of a     citronellal-isopulegol cyclase, which serves for the biocatalytic     conversion of citronellal to isopulegol, in a method of production     of isopulegol by cyclization of citronellal. -   42. Use of a host cell which comprises a gene construct or a vector     comprising a nucleic acid sequence according to SEQ ID NO: 1 or a     functional equivalent thereof, for preparing an enzyme having the     activity of a citronellal-isopulegol cyclase for the biocatalytic     conversion of citronellal to isopulegol.

C. Further Embodiments of the Invention 1. Especially Suitable Wild-Type Sequences

SHO wild-type sequences usable according to the invention, whose SEQ ID NO, source organism, GenBank reference number, the amino acid residue “corresponding” to position F486 of SEQ ID NO:2, i.e. F486-analog (“Aa”) and whose sequence position are presented in the following table. The information is based on a sequence alignment, which was set up as follows:

Program: CLUSTALW, Default parameters: Protein Gap Open Penalty 10.0 Protein Gap Extension Penalty  0.2 Protein weight matrix: Gonnet series GI No. of the reference S_ID DB SEQ ID NO Organism sequences Aa Position s1 seq_ID 2 Zymomonas mobilis AAV90172.1 F 486 s20 seq_ID 3 Streptomyces coelicolor CAB39697.1 F 449 s911 seq_ID 4 Acetobacter pasteurianus BAH99456.1 F 481 s2 seq_ID 5 Bradyrhizobium sp. ABQ33590.1 F 447 s940 seq_ID 6 Zymomonas mobilis EER62728.1 F 438 s949 seq_ID 7 Acidithiobacillus caldus EET25937.1 Y 432 s167 seq_ID 8 Acidithiobacillus ferrooxidans ACH84004.1 Y 429 s41 seq_ID 9 Acidobacterium capsulatum ACO34244.1 F 458 s36 seq_ID 10 Acidothermus cellulolyticus ABK53469.1 F 426 s83 seq_ID 11 Adiantum capillus-veneris BAF93209.1 Y 436 s143 seq_ID 12 Ajellomyces capsulatus EDN09769.1 F 496 s995 seq_ID 13 Ajellomyces capsulatus EER40510.1 — 432 s163 seq_ID 14 Ajellomyces capsulatus EEH02950.1 F 429 s13 seq_ID 15 Alicyclobacillus acidocaldarius EED08231.1 Y 420 s14 seq_ID 16 Alicyclobacillus acidocaldarius P33247.4 Y 420 s1193 seq_ID 17 Alicyclobacillus acidocaldarius AAT70690.1 Y 116 s21 seq_ID 18 Alicyclobacillus acidoterrestris CAA61950.1 Y 420 s1189 seq_ID 19 Alicyclobacillus acidoterrestris AAT70691.1 Y 121 s51 seq_ID 20 Anabaena variabilis ABA24268.1 F 423 s76 seq_ID 21 Anaeromyxobacter sp. ABS28257.1 F 440 s159 seq_ID 22 Aspergillus clavatus EAW07713.1 F 446 s131 seq_ID 23 Aspergillus flavus EED48353.1 F 444 s176 seq_ID 24 Aspergillus fumigatus EDP50814.1 F 502 s126 seq_ID 25 Aspergillus fumigatus EAL84865.1 F 449 s178 seq_ID 26 Aspergillus fumigatus EAL86291.2 F 406 s121 seq_ID 27 Aspergillus niger CAK43501.1 F 441 s115 seq_ID 28 Aspergillus niger CAK45506.1 F 440 s124 seq_ID 29 Aspergillus oryzae BAE63941.1 F 444 s119 seq_ID 30 Azotobacter vinelandii EAM07611.1 F 442 s223 seq_ID 31 Bacillus amyloliquefaciens ABS74269.1 F 413 s221 seq_ID 32 Bacillus anthracis AAP27368.1 F 409 s976 seq_ID 33 Bacillus cereus EEK66523.1 F 423 s225 seq_ID 34 Bacillus cereus EAL12758.1 F 423 s972 seq_ID 35 Bacillus cereus EEL44583.1 F 412 s977 seq_ID 36 Bacillus cereus EEK43841.1 F 412 s985 seq_ID 37 Bacillus cereus EEK82938.1 F 412 s988 seq_ID 38 Bacillus cereus EEK99528.1 F 412 s981 seq_ID 39 Bacillus cereus EEK77935.1 F 412 s987 seq_ID 40 Bacillus cereus EEL81079.1 F 412 s960 seq_ID 41 Bacillus cereus EEK88307.1 F 412 S979 seq_ID 42 Bacillus cereus EEL63943.1 F 412 s974 seq_ID 43 Bacillus cereus EEL59884.1 F 412 s956 seq_ID 44 Bacillus cereus EEL69857.1 F 412 s951 seq_ID 45 Bacillus cereus EEL92663.1 F 412 s986 seq_ID 46 Bacillus cereus EEL49968.1 F 411 s227 seq_ID 47 Bacillus cereus AAU16998.1 F 409 s224 seq_ID 48 Bacillus cereus AAS42477.1 F 409 s212 seq_ID 49 Bacillus cereus ACK95843.1 F 409 s289 seq_ID 50 Bacillus coahuilensis 205373680 F 276 s219 seq_ID 51 Bacillus cytotaxicus ABS22481.1 F 411 s230 seq_ID 52 Bacillus licheniformis AAU23777.1 F 414 s955 seq_ID 53 Bacillus mycoides EEL98438.1 F 412 s990 seq_ID 54 Bacillus mycoides EEM04821.1 F 411 s989 seq_ID 55 Bacillus pseudomycoides EEM16144.1 F 411 s247 seq_ID 56 Bacillus pumilus ABV62529.1 F 409 s250 seq_ID 57 Bacillus pumilus EDW21137.1 F 409 s249 seq_ID 58 Bacillus sp. EAR64404.1 F 425 s218 seq_ID 59 Bacillus sp. EDL66148.1 F 412 s241 seq_ID 60 Bacillus subtilis Q796C3.1 F 415 s284 seq_ID 61 Bacillus subtilis AAB84441.1 F 415 s215 seq_ID 62 Bacillus thuringiensis ABK86448.1 F 423 s984 seq_ID 63 Bacillus thuringiensis EEM21409.1 F 412 s957 seq_ID 64 Bacillus thuringiensis EEM82653.1 F 412 s980 seq_ID 65 Bacillus thuringiensis EEM52372.1 F 412 s961 seq_ID 66 Bacillus thuringiensis EEM27851.1 F 412 s969 seq_ID 67 Bacillus thuringiensis EEM40716.1 F 412 s959 seq_ID 68 Bacillus thuringiensis EEM46814.1 F 409 s965 seq_ID 69 Bacillus thuringiensis EEM94969.1 F 409 s202 seq_ID 70 Bacillus weihenstephanensis ABY44436.1 F 409 s63 seq_ID 71 Bacterium Ellin514 EEF57225.1 F 461 s72 seq_ID 72 Bacterium Ellin514 EEF59508.1 Y 435 s87 seq_ID 73 Beijerinckia indica ACB96717.1 F 441 s69 seq_ID 74 Blastopirellula marina EAQ81955.1 F 475 s543 seq_ID 75 Blastopirellula marina EAQ78122.1 F 389 s156 seq_ID 76 Bradyrhizabium japonicum CAA60250.1 F 439 s938 seq_ID 77 Acetobacter pasteurianus BAH98349.1 F 437 s3 seq_ID 78 Bradyrhizobium sp. CAL79893.1 F 447 s201 seq_ID 79 Brevibacillus brevis BAH44778.1 F 448 s148 seq_ID 80 Burkholderia ambifaria EDT05097.1 F 450 s158 seq_ID 81 Burkholderia ambifaria EDT37649.1 F 450 s149 seq_ID 82 Burkholderia ambifaria ACB68303.1 F 446 s100 seq_ID 83 Burkholderia ambifaria EDT42454.1 F 436 s146 seq_ID 84 Burkholderia cenocepacia EAY66961.1 F 451 s139 seq_ID 85 Burkholderia cenocepacia ACA95661.1 F 451 s147 seq_ID 86 Burkholderia cenocepacia CAR57099.1 F 451 s95 seq_ID 87 Burkholderia cenocepacia CAR56694.1 F 436 s102 seq_ID 88 Burkholderia dolosa EAY71311.1 F 437 s941 seq_ID 89 Burkholderia glumae ACR32572.1 F 555 s945 seq_ID 90 Burkholderia glumae ACR30752.1 F 449 s132 seq_ID 91 Burkholderia graminis EDT12320.1 F 462 s104 seq_ID 92 Burkholderia mallei ABM48844.1 F 436 s140 seq_ID 93 Burkholderia multivorans ABX19650.1 F 450 s116 seq_ID 94 Burkholderia multivorans ABX16859.1 F 436 s91 seq_ID 95 Burkholderia oklahomensis 167567074 F 447 s111 seq_ID 96 Burkholderia phymatum ACC73258.1 F 456 s127 seq_ID 97 Burkholderia phytofirmans ACD21317.1 F 455 s120 seq_ID 98 Burkholderia pseudamallei EEC32728.1 F 436 s137 seq_ID 99 Burkholderia sp. EEA03553.1 F 460 s144 seq_ID 100 Burkholderia sp. ABB06563.1 F 450 s98 seq_ID 101 Burkholderia sp. ABB10136.1 F 436 s944 seq_ID 102 Burkholderia sp. CCGE1002 EFA54357.1 F 473 s89 seq_ID 103 Burkholderia thailandensis 167840988 F 451 s113 seq_ID 104 Burkholderia thailandensis 167617352 F 442 s154 seq_ID 105 Burkholderia ubonensis 167589807 F 445 s93 seq_ID 106 Burkholderia ubonensis 167584986 F 436 s96 seq_ID 107 Burkholderia vietnamiensis ABO56791.1 F 436 s150 seq_ID 108 Burkholderia xenovorans ABE35912.1 F 457 s54 seq_ID 109 Candidatus Koribacter ABF40741.1 F 435 s171 seq_ID 110 Candidatus Kuenenia CAJ71215.1 F 273 s79 seq_ID 111 Candidatus Solibacter ABJ82180.1 F 439 s99 seq_ID 112 Candidatus Solibacter ABJ82254.1 F 429 s917 seq_ID 113 Catenulispora acidiphila ACU75510.1 F 418 s65 seq_ID 114 Chthoniobacter flavus EDY15838.1 F 433 s637 seq_ID 115 Chthoniobacter flavus EDY22035.1 F 384 s38 seq_ID 116 Crocosphaera watsonii EAM53094.1 F 426 s186 seq_ID 117 Cupriavidus taiwanensis CAQ72562.1 F 454 s32 seq_ID 118 Cyanothece sp. ACB53858.1 F 441 s40 seq_ID 119 Cyanothece sp. ACK71719.1 F 430 s30 seq_ID 120 Cyanothece sp. EDY02410.1 F 429 s29 seq_ID 121 Cyanothece sp. ACK66841.1 F 429 s47 seq_ID 122 Cyanothece sp. EDX97382.1 F 428 s35 seq_ID 123 Cyanothece sp. EAZ91809.1 F 426 s39 seq_ID 124 Cyanothece sp. ACL45896.1 F 423 s925 seq_ID 125 Cyanothece sp. PCC 8802 ACV02092.1 F 429 s64 seq_ID 126 Desulfovibrio salexigens EEC62384.1 F 475 s74 seq_ID 127 Dryopteris crossirhizoma BAG68223.1 F 444 s59 seq_ID 128 Frankia alni CAJ61140.1 Y 533 s48 seq_ID 129 Frankia alni CAJ60090.1 F 493 s56 seq_ID 130 Frankia sp. ABD10207.1 F 530 s60 seq_ID 131 Frankia sp. ABW15063.1 F 512 s31 seq_ID 132 Frankia sp. ABW14125.1 Y 481 s948 seq_ID 133 Frankia sp. Eul1c EFA59873.1 F 557 s919 seq_ID 134 Frankia sp. Eul1c EFA59089.1 F 553 s628 seq_ID 135 Gemmata obscuriglobus 168700710 F 387 s209 seq_ID 136 Geobacillus sp. EED61885.1 F 404 s206 seq_ID 137 Geobacillus sp. EDY05760.1 F 403 s964 seq_ID 138 Geobacillus sp. Y412MC52 EEN95021.1 F 404 s993 seq_ID 139 Geobacillus sp. Y412MC61 ACX79399.1 F 404 s205 seq_ID 140 Geobacillus thermodenitrificans ABO67242.1 F 403 s15 seq_ID 141 Geobacter bemidjiensis ACH40355.1 F 468 s8 seq_ID 142 Geobacter lovleyi ACD95949.1 F 470 s62 seq_ID 143 Geobacter metallireducens ABB30662.1 F 493 s12 seq_ID 144 Geobacter metallireducens ABB33038.1 F 467 s73 seq_ID 145 Geobacter sp. ACM21577.1 F 487 s10 seq_ID 146 Geobacter sp. EDV72707.1 F 468 s11 seq_ID 147 Geobacter sp. ACM22003.1 F 467 s913 seq_ID 148 Geobacter sp. M18 EET34621.1 F 468 s914 seq_ID 149 Geobacter sp. M21 ACT16952.1 F 468 s58 seq_ID 150 Geobacter sulfurreducens AAR36453.1 F 493 s7 seq_ID 151 Geobacter sulfurreducens AAR34018.1 F 467 s9 seq_ID 152 Geobacter uraniireducens ABQ25226.1 F 467 s46 seq_ID 153 Gloeobacter violaceus BAC91998.1 F 425 s67 seq_ID 154 Gluconacetobacter diazotrophicus ACI51585.1 F 444 s165 seq_ID 155 Gluconacetobacter diazotrophicus CAP55563.1 F 444 s68 seq_ID 156 Gluconobacter oxydans AAW61994.1 F 445 s80 seq_ID 157 Granulibacter bethesdensis ABI63005.1 F 429 s937 seq_ID 158 Hyphomicrobium denitrificans EET65847.1 F 444 s932 seq_ID 159 Leptospirillum ferrodiazotrophum EES53667.1 F 460 s24 seq_ID 160 Leptospirillum rubarum EAY57382.1 F 448 s25 seq_ID 161 Leptospirillum sp. EDZ38599.1 F 448 s174 seq_ID 162 Magnaporthe grisea EDK02551.1 F 445 s153 seq_ID 163 Magnetospirillum magnetotacticum 46203107 F 447 s49 seq_ID 164 Methylacidiphilum infernorum ACD82457.1 F 456 s169 seq_ID 165 Methylobacterium chloromethanicum ACK83067.1 F 447 s75 seq_ID 166 Methylobacterium chloromethanicum ACK38232.1 F 426 s946 seq_ID 167 Methylobacterium extorquens CAX24364.1 F 447 s141 seq_ID 168 Methylobacterium nodulans ACL61886.1 F 442 s152 seq_ID 169 Methylobacterium populi ACB79998.1 F 447 s162 seq_ID 170 Methylobacterium radiotolerans ACB27373.1 F 445 s180 seq_ID 171 Methylobacterium sp. ACA20611.1 F 442 s175 seq_ID 172 Methylocella silvestris ACK52150.1 F 451 s181 seq_ID 173 Methylococcus capsulatus CAA71098.1 F 439 s55 seq_ID 174 Microcystis aeruginosa CAO86472.1 F 423 s101 seq_ID 175 Neosartorya fischeri EAW20752.1 F 448 s129 seq_ID 176 Nitrobacter hamburgensis ABE63461.1 F 433 s161 seq_ID 177 Nitrobacter sp. EAQ34404.1 F 430 s160 seq_ID 178 Nitrobacter winogradskyi ABA05523.1 F 433 s157 seq_ID 179 Nitrococcus mobilis EAR22397.1 F 436 s164 seq_ID 180 Nitrosococcus oceani ABA57818.1 F 446 s170 seq_ID 181 Nitrosomonas europaea CAD85079.1 F 452 s173 seq_ID 182 Nitrosomonas eutropha ABI59752.1 F 456 s943 seq_ID 183 Nitrosomonas sp. AL212 EET32702.1 F 452 s142 seq_ID 184 Nitrosospira multiformis ABB75845.1 F 439 s52 seq_ID 185 Nostoc punctiforme ACC84529.1 F 423 s45 seq_ID 186 Nostoc sp. BAB72732.1 F 423 s122 seq_ID 187 Oligotropha carboxidovorans ACI93782.1 F 433 s233 seq_ID 188 Paenibacillus sp. EDS49994.1 F 399 s991 seq_ID 189 Paenibacillus sp. JDR-2 ACS99948.1 F 399 s950 seq_ID 190 Paenibacillus sp. oral taxon 786 EES74793.1 F 428 s1280 seq_ID 191 Paramecium tetraurelia 145542269 F 400 s71 seq_ID 192 Pelobacter carbinolicus ABA87701.1 F 494 s5 seq_ID 193 Pelobacter carbinolicus ABA87615.1 F 435 s66 seq_ID 194 Pelobacter propionicus ABK98395.1 F 486 s16 seq_ID 195 Pelobacter propionicus ABK98811.1 F 467 s136 seq_ID 196 Penicillium chrysogenum CAP99707.1 F 440 s936 seq_ID 197 Planctomyces limnophilus EEO67214.1 F 490 s1158 seq_ID 198 Planctomyces limnophilus EEO68341.1 F 412 s526 seq_ID 199 Planctomyces maris EDL58855.1 F 392 s992 seq_ID 200 Polypodiodes niponica BAI48071.1 Y 521 s942 seq_ID 201 Polypodiodes niponica BAI48070.1 F 443 s1202 seq_ID 202 Populus trichocarpa EEF12098.1 F 162 s168 seq_ID 203 Ralstonia eutropha AAZ64302.1 F 452 s190 seq_ID 204 Ralstonia eutropha CAJ96989.1 F 451 s81 seq_ID 205 Ralstonia metallidurans ABF11015.1 F 448 s110 seq_ID 206 Ralstonia metallidurans ABF11268.1 F 430 s123 seq_ID 207 Rhizobium sp. P55348.1 F 433 s657 seq_ID 208 Rhodopirellula baltica CAD74517.1 F 428 s4 seq_ID 209 Rhodopseudomonas palustris ABJ08391.1 F 445 s130 seq_ID 210 Rhodopseudomonas palustris CAA71101.1 F 433 s155 seq_ID 211 Rhodopseudomonas palustris ABD06434.1 F 433 s97 seq_ID 212 Rhodopseudomonas palustris ABD87279.1 F 433 s135 seq_ID 213 Rhodopseudomonas palustris ACF02757.1 F 432 s84 seq_ID 214 Rhodospirillum rubrum ABC20867.1 F 437 s1279 seq_ID 215 Rubrobacter xylanophilus ABG05671.1 F 372 s915 seq_ID 216 Saccharomonospora viridis ACU97316.1 F 428 s42 seq_ID 217 Saccharopolyspora erythraea CAM03596.1 F 421 s82 seq_ID 218 Schizosaccharomyces japonicus EEB08219.1 F 437 s923 seq_ID 219 Sphaerobacter thermophilus ACZ39437.1 F 404 s924 seq_ID 220 Streptomyces albus 239983547 F 371 s23 seq_ID 221 Streptomyces avermitilis BAC69361.1 F 450 s44 seq_ID 222 Acaryochloris marina ABW29816.1 F 423 s921 seq_ID 223 Streptomyces filamentosus 239945642 F 447 s934 seq_ID 224 Streptomyces flavogriseus EEW70811.1 F 447 s920 seq_ID 225 Streptomyces ghanaensis 239927462 F 448 s922 seq_ID 226 Streptomyces griseoflavus 256812310 F 448 s28 seq_ID 227 Streptomyces griseus BAG17791.1 F 447 s926 seq_ID 228 Streptomyces hygroscopicus 256775136 F 414 s916 seq_ID 229 Streptomyces lividans 256783789 F 449 s33 seq_ID 230 Streptomyces peucetius ACA52082.1 F 455 s27 seq_ID 231 Streptomyces pristinaespiralis EDY61772.1 F 455 s933 seq_ID 232 Streptomyces scabiei CBG68454.1 F 447 s37 seq_ID 233 Streptomyces sp. EDX25760.1 F 453 s34 seq_ID 234 Streptomyces sp. EDY46371.1 F 453 s931 seq_ID 235 Streptomyces sp. AA4 256668250 F 428 s918 seq_ID 236 Streptomyces sp. C 256770952 F 454 s929 seq_ID 237 Streptomyces sp. Mg1 254385931 F 453 s928 seq_ID 238 Streptomyces sp. SPB74 254379682 F 453 s930 seq_ID 239 Streptomyces sp. SPB78 256680470 F 404 s26 seq_ID 240 Streptomyces sviceus EDY55942.1 F 453 s927 seq_ID 241 Streptomyces viridochromogenes 256805984 F 447 s61 seq_ID 242 Synechococcus sp. EDX84551.1 F 426 s935 seq_ID 243 Synechococcus sp. PCC 7335 254422098 F 426 s53 seq_ID 244 Synechocystis sp. BAA17978.1 F 428 s22 seq_ID 245 Syntrophobacter fumaroxidans ABK18414.1 F 478 s6 seq_ID 246 Syntrophobacter fumaroxidans ABK17672.1 F 457 s912 seq_ID 247 Teredinibacter turnerae ACR13362.1 F 438 s57 seq_ID 248 Thermosynechococcus elongatus BAC09861.1 F 425 s43 seq_ID 249 Trichodesmium erythraeum ABG50159.1 F 418 s1178 seq_ID 250 Uncultured organism ACA58560.1 F 118 s1176 seq_ID 251 Uncultured organism ABL07557.1 F 118 s1165 seq_ID 252 Uncultured organism ACA58559.1 F 116 s1166 seq_ID 253 Uncultured organism ACA58558.1 F 116 s1168 seq_ID 254 Uncultured organism ABL07560.1 F 116 s1169 seq_ID 255 Uncultured organism ABL07565.1 F 116 s1170 seq_ID 256 Uncultured organism ABL07566.1 F 116 s1167 seq_ID 257 Uncultured organism ACA58545.1 F 116 s1171 seq_ID 258 Uncultured organism ACA58535.1 F 116 s1180 seq_ID 259 Uncultured organism ACA58549.1 F 116 s1179 seq_ID 260 Uncultured organism ACA58554.1 F 116 s1181 seq_ID 261 Uncultured organism ACA58555.1 F 116 s1182 seq_ID 262 Uncultured organism ACA58556.1 F 116 s1235 seq_ID 263 Uncultured organism ACA58530.1 F 116 s1188 seq_ID 264 Uncultured organism ACA58534.1 F 115 s1237 seq_ID 265 Uncultured organism ACA58552.1 F 115 s1223 seq_ID 266 Uncultured organism ABL07558.1 F 115 s1200 seq_ID 267 Uncultured organism ABL07542.1 F 115 s1236 seq_ID 268 Uncultured organism ACA58539.1 F 114 s1238 seq_ID 269 Uncultured organism ACA58537.1 F 114 s1233 seq_ID 270 Uncultured organism ACA58543.1 F 114 s1173 seq_ID 271 Uncultured organism ABL07553.1 F 114 s1241 seq_ID 272 Uncultured organism ABL07540.1 F 114 s1242 seq_ID 273 Uncultured organism ABL07544.1 F 114 s1225 seq_ID 274 Uncultured organism ACA58557.1 F 114 s1183 seq_ID 275 Uncultured organism ACA58520.1 F 113 s1197 seq_ID 276 Uncultured organism ACA58524.1 F 113 s1185 seq_ID 277 Uncultured organism ACA58522.1 F 113 s1190 seq_ID 278 Uncultured organism ACA58525.1 F 113 s1187 seq_ID 279 Uncultured organism ACA58523.1 F 113 s1184 seq_ID 280 Uncultured organism ACA58521.1 F 113 s1204 seq_ID 281 Uncultured organism ACA58547.1 F 113 s1221 seq_ID 282 Uncultured organism ACA58544.1 F 113 s1198 seq_ID 283 Uncultured organism ACA58546.1 F 112 s1226 seq_ID 284 Uncultured organism ACA58527.1 F 112 s1227 seq_ID 285 Uncultured organism ABL07537.1 F 112 s1232 seq_ID 286 Uncultured organism ACA58510.1 F 112 s1230 seq_ID 287 Uncultured organism ACA58538.1 F 112 s1229 seq_ID 288 Uncultured organism ACA58542.1 F 112 s1231 seq_ID 289 Uncultured organism ACA58540.1 F 112 s1207 seq_ID 290 Uncultured organism ABL07564.1 F 112 s1212 seq_ID 291 Uncultured organism ABL07563.1 F 112 s1208 seq_ID 292 Uncultured organism ABL07562.1 F 112 s1209 seq_ID 293 Uncultured organism ABL07559.1 F 112 s1214 seq_ID 294 Uncultured organism ABL07556.1 F 112 s1216 seq_ID 295 Uncultured organism ACA58528.1 F 112 s1219 seq_ID 296 Uncultured organism ACA58536.1 F 112 s1192 seq_ID 297 Uncultured organism ABL07533.1 F 112 s1195 seq_ID 298 Uncultured organism ABL07536.1 F 112 s1174 seq_ID 299 Uncultured organism ABL07545.1 F 112 s1186 seq_ID 300 Uncultured organism ABL07548.1 F 112 s1196 seq_ID 301 Uncultured organism ACA58561.1 F 112 s1172 seq_ID 302 Uncultured organism ABL07555.1 F 112 s1194 seq_ID 303 Uncultured organism ABL07541.1 F 112 s1211 seq_ID 304 Uncultured organism ABL07554.1 F 112 s1220 seq_ID 305 Uncultured organism ABL07547.1 F 112 s1203 seq_ID 306 Uncultured organism ABL07550.1 F 112 s1199 seq_ID 307 Uncultured organism ABL07551.1 F 112 s1228 seq_ID 308 Uncultured organism ACA58509.1 F 111 s1201 seq_ID 309 Uncultured organism ACA58514.1 F 111 s1205 seq_ID 310 Uncultured organism ABL07543.1 F 111 s1206 seq_ID 311 Uncultured organism ABL07534.1 F 111 s1177 seq_ID 312 Uncultured organism ABL07546.1 F 111 s1210 seq_ID 313 Uncultured organism ABL07535.1 F 111 s1175 seq_ID 314 Uncultured organism ABL07552.1 F 111 s1191 seq_ID 315 Uncultured organism ABL07549.1 F 111 s1222 seq_ID 316 Uncultured organism ACA58553.1 F 111 s1244 seq_ID 317 Uncultured organism ABL07539.1 F 111 s1213 seq_ID 318 Uncultured organism ACA58532.1 F 110 s1239 seq_ID 319 Uncultured organism ACA58548.1 F 110 s1215 seq_ID 320 Uncultured organism ABL07561.1 F 110 s1240 seq_ID 321 Uncultured organism ACA58533.1 F 110 s1234 seq_ID 322 Uncultured organism ABL07538.1 F 109 s1224 seq_ID 323 Uncultured organism ACA58541.1 F 109 s1217 seq_ID 324 Uncultured organism ACA58529.1 F 109 s596 seq_ID 325 Verrucomicrobium spinosum 171910093 F 395 s70 seq_ID 326 Acidiphilium cryptum ABQ30890.1 F 430

Further potential cyclase mutants with the desired substrate properties can be produced starting from these, on the basis of the findings for mutants of Zm-SHC-1.

2. Further Proteins/Enzyme Mutants According to the Invention

The present invention is not limited to the mutants with cyclase activity concretely disclosed herein, but rather also extends to functional equivalents thereof.

“Functional equivalents” or analogs of the concretely disclosed enzymes and enzyme mutants (F486 and “F486-analog” mutants, derived from SEQ ID NO: 2 to 326, in particular SEQ ID NO: 2 to 6) are, within the scope of the present invention, various polypeptides thereof, which furthermore possess the desired biological activity, for example cyclase activity.

For example “functional equivalents” are understood to include enzymes and mutants that have, in a test applied for “cyclase activity” in the sense of the invention (i.e. with a reference substrate under standard conditions), an at least 1%, in particular at least about 5 to 10%, for example at least 10% or at least 20%, for example at least 50% or 75% or 90% higher or lower activity of an enzyme, comprising an amino acid sequence concretely defined herein (e.g. an F486 and “F486-analog” mutant, derived from SEQ ID NO: 2 to 326; in particular SEQ ID NO: 2 to 6).

The activity information for functional equivalents refers herein, unless stated otherwise, to activity determinations, performed by means of a reference substrate under standard conditions, as defined herein.

The “cyclase activity” in the sense of the invention can be detected by means of various known tests. Without being limited to this, we may mention a test using a reference substrate, for example citronellal racemate or R(+) form, under standard conditions, as described above and explained in the experimental section.

Functional equivalents are moreover stable e.g. between pH 4 to 11 and advantageously possess a pH optimum in a range from pH 5 to 10, such as in particular 6.5 to 9.5 or 7 to 8 or at about 7.5, and a temperature optimum in the range from 15° C. to 80° C. or 20° C. to 70° C., for example about 30 to 60° C. or about 35 to 45° C., such as at 40° C.

“Functional equivalents” are to be understood according to the invention to include in particular also “mutants”, which, as well as the concretely stated mutation(s) (e.g. an F486 and “F486-analog” mutant, derived from SEQ ID NO: 2 to 326, in particular SEQ ID NO: 2 to 6), have in at least one sequence position of the aforementioned amino acid sequences, an amino acid other than that concretely stated, but nevertheless possess one of the aforementioned biological activities.

“Functional equivalents” comprise the mutants obtainable by one or more, for example 1 to 50, 2 to 30, 2 to 15, 4 to 12 or 5 to 10 “additional mutations”, such as amino acid additions, substitutions, deletions and/or inversions, wherein the stated changes can occur in any sequence position, provided they lead to a mutant with the property profile according to the invention. Functional equivalence is in particular also present when the reactivity profiles between mutant and unaltered polypeptide coincide qualitatively, i.e. for example the same substrates are converted at a different rate.

“Additional mutations” of this kind occur at a position of the respective amino acid sequence different from position F486 according to SEQ ID NO: 2 or from the F486-analog position according to one of SEQ ID NOs: 3 to 326, in particular SEQ ID NO: 3 to 6.

Nonlimiting examples of suitable amino acid substitutions are given in the following table:

Original residue Examples of substitution Ala Ser Arg Lys Asn Gln; His Asp Glu Cys Ser Gln Asn Glu Asp Gly Pro His Asn; Gln Ile Leu; Val Leu Ile; Val Lys Arg; Gln; Glu Met Leu; Ile Phe Met; Leu; Tyr Ser Thr Thr Ser Trp Tyr Tyr Trp; Phe Val Ile; Leu

“Functional equivalents” in the above sense are also “precursors” of the polypeptides described as well as “functional derivatives” and “salts” of the polypeptides.

“Precursors” are natural or synthetic precursors of the polypeptides with or without the desired biological activity.

The term “salts” means both salts of carboxyl groups and salts of acid addition of amino groups of the protein molecules according to the invention. Salts of carboxyl groups can be produced in a manner known per se and comprise inorganic salts, for example sodium, calcium, ammonium, iron and zinc salts, and salts with organic bases, for example amines, such as triethanolamine, arginine, lysine, piperidine and the like. Salts of acid addition, for example salts with mineral acids, such as hydrochloric acid or sulfuric acid and salts with organic acids, such as acetic acid and oxalic acid, are also objects of the invention.

“Functional derivatives” of polypeptides according to the invention can also be produced on functional amino acid side groups or at their N- or C-terminal end by known techniques.

Derivatives of this kind comprise for example aliphatic esters of carboxylic acid groups, amides of carboxylic acid groups, obtainable by reaction with ammonia or with a primary or secondary amine; N-acyl derivatives of free amino groups, produced by reaction with acyl groups; or O-acyl derivatives of free hydroxyl groups, produced by reaction with acyl groups.

“Functional equivalents” naturally also comprise polypeptides that are accessible from other organisms, and naturally occurring variants. For example areas of homologous sequence regions can be established by sequence comparison and equivalent enzymes can be determined based on the concrete information of the invention.

“Functional equivalents” also comprise fragments, preferably individual domains or sequence motifs, of the polypeptides according to the invention, which for example have the desired biological function.

“Functional equivalents” are moreover fusion proteins, which have one of the aforementioned polypeptide sequences or functional equivalents derived therefrom and at least one further, functionally different therefrom, heterologous sequence in functional N- or C-terminal linkage (i.e. without mutual substantial functional impairment of the fusion protein parts). Nonlimiting examples of heterologous sequences of this kind are e.g. signal peptides, histidine anchors or enzymes.

“Functional equivalents” that are also included according to the invention are homologs to the concretely disclosed proteins. These possess at least 60%, preferably at least 75%, especially at least 85%, for example 90, 91, 92, 93, 94, 95, 96, 97, 98 or 99%, homology (or identity) to one of the concretely disclosed amino acid sequences, calculated using the algorithm of Pearson and Lipman, Proc. Natl. Acad. Sci. (USA) 85(8), 1988, 2444-2448. A percentage homology or identity of a homologous polypeptide according to the invention means in particular percentage identity of the amino acid residues relative to the total length of one of the amino acid sequences concretely described herein. In particular, however, these homologs also have the F486 or “F486-analog” mutation, derived from SED ID NO:2 to 326, in particular SEQ ID NO: 2 to 6.

The percentage identity values can also be determined on the basis of BLAST alignments, blastp algorithms (protein-protein BLAST), or using the Clustal settings given below.

In the case of a possible protein glycosylation, “functional equivalents” according to the invention comprise proteins of the type designated above in deglycosylated or glycosylated form as well as modified forms obtainable by changing the glycosylation pattern.

Homologs of the proteins or polypeptides according to the invention can be produced by mutagenesis, e.g. by point mutation, lengthening or shortening of the protein.

Homologs of the proteins according to the invention can be identified by screening combinatorial databases of mutants, for example shortened mutants. For example a variegated database of protein variants can be produced by combinatorial mutagenesis at nucleic acid level, for example by enzymatic ligation of a mixture of synthetic oligonucleotides. There are a great many methods that can be used for producing databases of potential homologs from a degenerated oligonucleotide sequence. The chemical synthesis of a degenerated gene sequence can be carried out in an automatic DNA synthesizer, and the synthetic gene can then be ligated into a suitable expression vector. The use of a degenerated set of genes makes it possible to provide all sequences, in one mixture, which code for the desired set of potential protein sequences. Methods for the synthesis of degenerated oligonucleotides are known by a person skilled in the art (e.g. Narang, S. A. (1983) Tetrahedron 39:3; Itakura et al. (1984) Annu. Rev. Biochem. 53:323; Itakura et al., (1984) Science 198:1056; Ike et al. (1983) Nucleic Acids Res. 11:477).

Several techniques for screening gene products of combinatorial databases, which were produced by point mutations or shortening, and for screening cDNA databases for gene products with a chosen property, are known in the prior art. These techniques can be adapted for rapid screening of gene banks that have been produced by combinatorial mutagenesis of homologs according to the invention. The techniques used most often for screening large gene banks, as the basis for high-throughput analysis, comprise cloning the gene bank into replicatable expression vectors, transforming suitable cells with the resultant vector bank and expressing the combinatorial genes in conditions in which detection of the desired activity facilitates the isolation of the vector that codes for the gene whose product was detected. Recursive ensemble mutagenesis (REM), a technique that increases the frequency of functional mutants in the databases, can be used in combination with the screening tests, to identify homologs (Arkin and Yourvan (1992) PNAS 89:7811-7815; Delgrave et al. (1993) Protein Engineering 6(3):327-331).

3. Nucleic Acids and Constructs 3.1 Nucleic Adds

The invention also relates to nucleic acid sequences that code for an enzyme as described above or a mutant thereof described above with cyclase activity.

The present invention also relates to nucleic acids with a specified degree of identity to the concrete sequences described herein.

“Identity” between two nucleic acids means identity of the nucleotides in each case over the whole length of nucleic acid, in particular the identity that is calculated by comparison by means of the Vector NTI Suite 7.1 software from the company Informax (USA) using the Clustal method (Higgins D G, Sharp P M. Fast and sensitive multiple sequence alignments on a microcomputer. Comput Appl. Biosci. 1989 Apr.; 5(2):151-1), setting the following parameters:

Multiple Alignment Parameters:

Gap opening penalty 10 Gap extension penalty 10 Gap separation penalty range 8 Gap separation penalty off % identity for alignment delay 40 Residue specific gaps off Hydrophilic residue gap off Transition weighting 0

Pairwise Alignment Parameter:

FAST algorithm on K-tuple size 1 Gap penalty 3 Window size 5 Number of best diagonals 5

As an alternative, the identity can also be determined according to Chema, Ramu, Sugawara, Hideaki, Koike, Tadashi, Lopez, Rodrigo, Gibson, Toby J, Higgins, Desmond G, Thompson, Julie D. Multiple sequence alignment with the Clustal series of programs. (2003) Nucleic Acids Res 31 (13):3497-500, according to Internet address: ebi.ac.ukiTools/clustalw/index.htrnl# and with the following parameters:

DNA Gap Open Penalty 15.0 DNA Gap Extension Penalty 6.66 DNA Matrix Identity Protein Gap Open Penalty 10.0 Protein Gap Extension Penalty 0.2 Protein matrix Gonnet Protein/DNA ENDGAP −1 Protein/DNA GAPDIST 4

All nucleic acid sequences mentioned herein (single-stranded and double-stranded DNA and RNA sequences, for example cDNA and mRNA) can be produced in a manner known per se by chemical synthesis from the nucleotide building blocks, for example by fragment condensation of individual overlapping, complementary nucleic acid building blocks of the double helix. The chemical synthesis of oligonucleotides can for example be carried out in a known manner, by the phosphoroamidite technique (Voet. Voet, 2nd edition, Wiley Press New York, pages 896-897). The adding-on of synthetic oligonucleotides and filling of gaps using the Klenow fragment of DNA polymerase and ligation reactions as well as general cloning techniques are described in Sambrook et al. (1989), Molecular Cloning: A Laboratory Manual, Cold Spring Harbor Laboratory Press.

The invention also relates to nucleic acid sequences (single-stranded and double-stranded DNA and RNA sequences, for example cDNA and mRNA), coding for one of the above polypeptides and functional equivalents thereof, which are accessible e.g. using artificial nucleotide analogs.

The invention relates both to isolated nucleic acid molecules, which code for polypeptides or proteins according to the invention or biologically active segments thereof, and to nucleic acid fragments, which can be used for example as hybridization probes or primers for the identification or amplification of coding nucleic acids according to the invention.

The nucleic acid molecules according to the invention can in addition contain untranslated sequences of the 3′- and/or 5′-end of the coding gene region.

The invention further comprises the nucleic acid molecules complementary to the concretely described nucleotide sequences, or a segment thereof.

The nucleotide sequences according to the invention make it possible to produce probes and primers that can be used for the identification and/or cloning of homologous sequences in other cell types and organisms. Said probes or primers usually comprise a nucleotide sequence region which hybridizes under “stringent” conditions (see below) to at least about 12, preferably at least about 25, for example about 40, 50 or 75 successive nucleotides of a sense strand of a nucleic acid sequence according to the invention or of a corresponding antisense strand.

An “isolated” nucleic acid molecule is separate from other nucleic acid molecules that are present in the natural source of the nucleic acid, and moreover can be essentially free of other cellular material or culture medium, when it is produced by recombinant techniques, or free of chemical precursors or other chemicals, when it is chemically synthesized.

A nucleic acid molecule according to the invention can be isolated by standard techniques of molecular biology and the sequence information provided according to the invention. For example, cDNA can be isolated from a suitable cDNA-bank, using one of the concretely disclosed complete sequences or a segment thereof as hybridization probe and standard hybridization techniques (as described for example in Sambrook, Fritsch, E. F. and Maniatis, T. Molecular Cloning: A Laboratory Manual. 2nd edition, Cold Spring Harbor Laboratory, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y. 1989). Moreover, a nucleic acid molecule, comprising one of the disclosed sequences or a segment thereof, can be isolated by polymerase chain reaction, using the oligonucleotide primers that were constructed on the basis of this sequence. The nucleic acid thus amplified can be cloned into a suitable vector and can be characterized by DNA sequence analysis. The oligonucleotides according to the invention can moreover be produced by standard methods of synthesis, e.g. with an automatic DNA synthesizer.

Nucleic acid sequences according to the invention or derivatives thereof, homologs or parts of these sequences, can be isolated for example with usual hybridization methods or PCR techniques from other bacteria, e.g. via genomic or cDNA databases. These DNA sequences hybridize under standard conditions to the sequences according to the invention.

“Hybridization” means the capacity of a poly- or oligonucleotide to bind to an almost complementary sequence under standard conditions, whereas under these conditions nonspecific binding between noncomplementary partners does not occur. For this, the sequences can be up to 90-100% complementary. The property of complementary sequences of being able to bind specifically to one another is utilized for example in Northern or Southern blotting or in primer binding in PCR or RT-PCR.

Short oligonucleotides of the conserved regions are used advantageously for hybridization. However, longer fragments of the nucleic acids according to the invention or the complete sequences can also be used for hybridization. These standard conditions vary depending on the nucleic acid used (oligonucleotide, longer fragment or complete sequence) or depending on which type of nucleic acid. DNA or RNA, is used for hybridization. Thus, for example, the melting temperatures for DNA:DNA hybrids are approx. 10° C. lower than those of DNA:RNA hybrids of the same length.

Standard conditions mean for example, depending on the nucleic acid, temperatures between 42 and 58° C. in an aqueous buffer solution with a concentration between 0.1 to 5×SSC (1×SSC=0.15 M NaCl, 15 mM sodium citrate, pH 7.2) or additionally in the presence of 50% formamide, for example 42″C in 5×SSC, 50% formamide. Advantageously, the hybridization conditions for DNA:DNA hybrids are 0.1×SSC and temperatures between about 20° C. to 45° C., preferably between about 30° C. to 45° C. For DNA:RNA hybrids the hybridization conditions are advantageously 0.1×SSC and temperatures between about 30° C. to 55° C., preferably between about 45° C. to 55° C. These stated temperatures for hybridization are for example calculated melting temperature values for a nucleic acid with a length of approx. 100 nucleotides and a G+C content of 50% in the absence of formamide. The experimental conditions for DNA hybridization are described in relevant textbooks on genetics, for example Sambrook et al., “Molecular Cloning”, Cold Spring Harbor Laboratory, 1989, and can be calculated using formulas known by a person skilled in the art, for example depending on the length of the nucleic acids, the type of hybrids or the G+C content. Further information on hybridization can be obtained by a person skilled in the art from the following textbooks: Ausubel et al. (eds), 1985, Current Protocols in Molecular Biology, John Wiley & Sons, New York; Hames and Higgins (eds), 1985, Nucleic Acids Hybridization: A Practical Approach, IRL Press at Oxford University Press, Oxford; Brown (ed), 1991, EssentialMolecular Biology: A Practical Approach, lRL Press at Oxford University Press, Oxford.

“Hybridization” can in particular take place under stringent conditions. Said hybridization conditions are described for example by Sambrook, J., Fritsch, E. F., Maniatis, T. in: Molecular Cloning (A Laboratory Manual), 2nd edition, Cold Spring Harbor Laboratory Press, 1989, pages 931-9.57 or in Current Protocols in Molecular Biology, John Wiley & Sons, N.Y. (1989), 6.3.1-6.3.6.

“Stringent” hybridization conditions mean in particular: Incubation at 42° C. overnight in a solution consisting of 50% formamide, 5×SSC (750 mM NaCl, 75 mM trisodium citrate), 50 mM sodium phosphate (pH7.6), 5×Denhardt solution, 10% dextran sulfate and 20 g/ml denatured, sheared salmon sperm DNA, followed by a step of washing the filters with 0.1×SSC at 85° C.

The invention also relates to derivatives of the concretely disclosed or derivable nucleic acid sequences.

Thus, further nucleic acid sequences according to the invention coding for cyclase mutants can be derived e.g. from SEQ ID NO: 1 or from the coding sequences for SEQ ID NO: 2 to 326, in particular SEQ ID NO: 2 to 6, by an F486 or F486-analog mutation and differ from them by addition, substitution, insertion or deletion of single or several nucleotides, but furthermore code for polypeptides with the desired property profile.

The invention also includes nucleic acid sequences that comprise so-called silent mutations or are altered corresponding to the codon-usage of a special original or host organism, compared with a concretely stated sequence, as well as naturally occurring variants, for example splice variants or allele variants, thereof.

It also relates to sequences obtainable by conservative nucleotide substitutions (i.e. the amino acid in question is replaced with an amino acid of the same charge, size, polarity and/or solubility).

The invention also relates to the molecules derived by sequence polymorphisms from the concretely disclosed nucleic acids. These genetic polymorphisms can exist between individuals within a population owing to natural variation. These natural variations usually bring about a variance of 1 to 5% in the nucleotide sequence of a gene.

Derivatives of the nucleic acid sequences according to the invention coding for cyclase mutants derived from sequence SEQ ID NO: 1 or from one of the coding sequences for SEQ ID NO: 2 to 326, in particular SEQ ID NO: 2 to 6, include for example allele variants that have at least 60% homology at the derived amino acid level, preferably at least 80% homology, quite especially preferably at least 90% homology over the whole sequence region (regarding homology at the amino acid level, reference should be made to the above account relating to polypeptides). The homologies can advantageously be higher over partial regions of the sequences.

Furthermore, derivatives also mean homologs of the nucleic acid sequences according to the invention, for example fungal or bacterial homologs, shortened sequences, single-strand DNA or RNA of the coding and noncoding DNA sequence.

Moreover, derivatives mean for example fusions with promoters. The promoters, which are added to the given nucleotide sequences, can be altered by at least one nucleotide exchange, at least one insertion, inversion and/or deletion, without the functionality or efficacy of the promoters being impaired. Moreover, the efficacy of the promoters can be increased by altering their sequence or they can be exchanged completely for more effective promoters even of organisms of a different species.

3.2 Generation of Functional Mutants

Furthermore, methods for producing functional mutants of enzymes according to the invention are known by a person skilled in the art.

Depending on the technology used, a person skilled in the art can introduce completely random or even more-directed mutations in genes or also nancoding nucleic acid regions (which for example are important for the regulation of expression) and then prepare gene libraries. The necessary methods of molecular biology are known by a person skilled in the art and for example are described in Sambrook and Russell, Molecular Cloning, 3rd edition, Cold Spring Harbor Laboratory Press 2001.

Methods for altering genes and therefore for altering the proteins that they encode have long been familiar to a person skilled in the art, for example

-   -   site-directed mutagenesis, in which single or several         nucleotides of a gene are deliberately exchanged (Trower M K         (Ed.); In vitro mutagenesis protocols, Humana Press, New         Jersey),     -   saturation mutagenesis, in which a codon for any amino acid can         be exchanged or added at any point of a gene (Kegler-Ebo D M,         Docktor C M, DiMaio D (1994) Nucleic Acids Res 22:1593;         Barettino D, Feigenbutz M, Valcárel R, Stunnenberg H G (1994)         Nucleic Acids Res 22:541; Barik S (1995) Mol Biotechnol 3:1),     -   the error-prone polymerase chain reaction (error-prone PCR), in         which nucleotide sequences are mutated by error-prone DNA         polymerases (Eckert K A, Kunkel T A (1990) Nucleic Acids Res         18:3739);     -   the SeSaM method (sequence saturation method), in which         preferred exchanges are prevented by the polymerase. Schenk et         al., Biospektrum, Vol. 3, 2006, 277-279     -   the passaging of genes in mutator strains, in which, for example         owing to defective DNA repair mechanisms, there is an increased         mutation rate of nucleotide sequences (Greener A, Callahan M.         Jerpseth B (1996) An efficient random mutagenesis technique         using an E. coli mutator strain. In: Trower M K (Ed.) in vitro         mutagenesis protocols. Humana Press, New Jersey), or     -   DNA shuffling, in which a pool of closely related genes is         formed and digested and the fragments are used as templates for         a polymerase chain reaction, in which, by repeated strand         separation and bringing together again, finally mosaic genes of         full length are produced (Stemmer W P C (1994) Nature 370:389;         Stemmer W P C (1994) Proc Natl Acad Sci USA 91:10747).

Using so-called directed evolution (described for instance in Reetz M T and Jaeger K-E (1999), Topics Curr Chem 200:31; Zhao H. Moore J C, Volkov A A, Arnold F H (1999), Methods for optimizing industrial enzymes by directed evolution, in: Demain A L, Davies J E (Ed.) Manual of industrial microbiology and biotechnology. American Society for Microbiology), a person skilled in the art can produce functional mutants in a directed manner and on a large scale. For this, in a first step, gene libraries of the respective proteins are first produced, for example using the methods given above. The gene libraries are expressed in a suitable way, for example by bacteria or by phage display systems.

The relevant genes of host organisms that express functional mutants with properties that largely correspond to the desired properties can be submitted to another round of mutation. The steps of mutation and selection or screening can be repeated iteratively until the present functional mutants have the desired properties to a sufficient extent. Using this iterative procedure, a limited number of mutations, for example 1, 2, 3, 4 or 5 mutations, can be effected in stages and can be assessed and selected for their influence on the enzyme property in question. The selected mutant can then be submitted to a further mutation step in the same way. In this way the number of individual mutants to be investigated can be reduced significantly.

The results according to the invention also provide important information relating to structure and sequence of the relevant enzymes, which is required for deliberately generating further enzymes with desired modified properties. In particular so-called “hot spots” can be defined, i.e. sequence segments that are potentially suitable for modifying an enzyme property by introducing targeted mutations.

Information can also be deduced regarding amino acid sequence positions, in the region of which mutations can be carried out that should probably have little effect on enzyme activity, and can be designated as potential “silent mutations”.

3.3 Constructs

The invention further relates to, in particular recombinant, expression constructs, containing, under the genetic control of regulatory nucleic acid sequences, a nucleic acid sequence coding for a polypeptide according to the invention; and, in particular recombinant, vectors, comprising at least one of these expression constructs.

An “expression unit” means, according to the invention, a nucleic acid with expression activity, which comprises a promoter, as defined herein, and after functional linkage with a nucleic acid to be expressed or a gene, regulates the expression, i.e. the transcription and the translation of said nucleic acid or said gene. Therefore in this connection it is also called a “regulatory nucleic acid sequence”. In addition to the promoter, other regulatory elements, for example enhancers, can also be present.

An “expression cassette” or “expression construct” means, according to the invention, an expression unit that is functionally linked to the nucleic acid to be expressed or the gene to be expressed. In contrast to an expression unit, an expression cassette therefore comprises not only nucleic acid sequences that regulate transcription and translation, but also the nucleic acid sequences that are to be expressed as protein as a result of the transcription and translation.

The terms “expression” or “overexpression” describe, in the context of the invention, the production or increase in intracellular activity of one or more enzymes in a microorganism, which are encoded by the corresponding DNA. For this, it is possible for example to introduce a gene into an organism, replace an existing gene with another gene, increase the copy number of the gene or genes, use a strong promoter or use a gene that codes for a corresponding enzyme with a high activity; optionally, these measures can be combined.

Preferably said constructs according to the invention comprise a promoter 5′-upstream of the respective coding sequence and a terminator sequence 3′-downstream and optionally other usual regulatory elements, in each case operatively linked with the coding sequence.

A “promoter”, of a “nucleic acid with promoter activity” or of a “promoter sequence” means, according to the invention, a nucleic acid which, functionally linked to a nucleic acid to be transcribed, regulates the transcription of said nucleic acid.

A “functional” or “operative” linkage means, in this connection, for example the sequential arrangement of one of the nucleic acids with promoter activity and of a nucleic acid sequence to be transcribed and optionally further regulatory elements, for example nucleic acid sequences that ensure the transcription of nucleic acids, and for example a terminator, in such a way that each of the regulatory elements can perform its function during transcription of the nucleic acid sequence. This does not necessarily require a direct linkage in the chemical sense. Genetic control sequences, for example enhancer sequences, can even exert their function on the target sequence from more remote positions or even from other DNA molecules. Arrangements are preferred in which the nucleic acid sequence to be transcribed is positioned behind (i.e. at the 3′-end of) the promoter sequence, so that the two sequences are joined together covalently. The distance between the promoter sequence and the nucleic acid sequence to be expressed transgenically can be smaller than 200 base pairs, or smaller than 100 base pairs or smaller than 50 base pairs.

In addition to promoters and terminator, the following may be mentioned as examples of other regulatory elements: targeting sequences, enhancers, polyadenylation signals, selectable markers, amplification signals, replication origins and the like. Suitable regulatory sequences are described for example in Goeddel, Gene Expression Technology: Methods in Enzymology 185, Academic Press, San Diego, Calif. (1990).

Nucleic acid constructs according to the invention comprise in particular a sequence coding for a cyclase mutant, e.g. derived from SEQ ID NO: 1 or coding for a mutant of SEQ ID NO: 2 to 326 or derivatives and homologs thereof, and the nucleic acid sequences derivable therefrom, which have been linked operatively or functionally with one or more regulatory signals advantageously for controlling, e.g. increasing, gene expression.

In addition to these regulatory sequences, the natural regulation of these sequences can still be present before the actual structural genes and optionally can have been genetically altered, so that the natural regulation has been switched off and expression of the genes has been increased. The nucleic acid construct can, however, also be of simpler construction, i.e. no additional regulatory signals have been inserted before the coding sequence and the natural promoter, with its regulation, has not been removed. Instead, the natural regulatory sequence is mutated so that regulation no longer takes place and gene expression is increased.

A preferred nucleic acid construct advantageously also contains one or more of the “enhancer” sequences already mentioned, functionally linked to the promoter, which make increased expression of the nucleic acid sequence possible. Additional advantageous sequences can also be inserted at the 3′-end of the DNA sequences, such as further regulatory elements or terminators. One or more copies of the nucleic acids according to the invention can be contained in the construct. The construct can also contain other markers, such as antibiotic resistances or auxotrophy complementing genes, optionally for selection on the construct.

Examples of suitable regulatory sequences are contained in promoters such as cos-, tac-, bp-, let-, trp-tet-, lpp-, lac-, lpp-lac-, lacl^(q), T7-, T5-, T3-, gal-, trc-, ara-, rhaP (rhaR_(BAD))SP6-, lambda-P_(R)- or in the lambda-P_(L)-promoter, which advantageously find application in gram-negative bacteria. Further advantageous regulatory sequences are contained for example in the gram-positive promoters amy and SPO2, in the yeast or fungal promoters ADC1, MFalpha, AC, P-60, CYC1, GAPDH, TEF, rp28, ADH, Artificial promoters can also be used for regulation.

For expression in a host organism, the nucleic acid construct is advantageously inserted into a vector, for example a plasmid or a phage, which makes optimal expression of the genes in the host possible. Apart from plasmids and phage, vectors are also to be understood as all other vectors known by a person skilled in the art, e.g. viruses, such as SV40. CMV, baculovirus and adenovirus, transposons. IS elements, phasmids, cosmids, and linear or circular DNA. These vectors can be replicated autonomously in the host organism or can be replicated chromosomally. These vectors represent a further embodiment of the invention.

Suitable plasmids are for example in E. coli pLG338, pACYC184, pBR322, pUC18, pKC30, pRep4, pHS1, pKK223-3, pDHE19.2, pHS2, pPLc236, pMBL24, pLG200, pUR290, pIN-III¹¹³-B1, λgt11 or pBdCl, in Streptomyces pIJ101, pIJ364, pIJ702 or pIJ361, in Bacillus pUB110, pC194 or pBD214, in Corynebacterium pSA77 or pAJ667, in fungi pALS1, plL2 or pBB116, in yeasts 2alphaM, pAG-1, YEp6. YEp13 or pEMBLYe23 or in plants pLGV23, pGHlac⁺, pBIN19, pAK2004 or pDH51. The stated plasmids represent a small selection of the possible plasmids. Further plasmids are well known by a person skilled in the art and can for example be found in the book Cloning Vectors (Eds. Pouwels P. H. et al. Elsevier, Amsterdam-New York-Oxford, 1985, ISBN 0 444 904018).

In another embodiment of the vector, the vector containing the nucleic acid construct according to the invention or the nucleic acid according to the invention can also advantageously be introduced in the form of a linear DNA into the microorganisms and integrated via heterologous or homologous recombination into the genome of the host organism. This linear DNA can consist of a linearized vector such as a plasmid or only of the nucleic acid construct or the nucleic acid according to the invention.

For optimal expression of heterologous genes in organisms, it is advantageous to alter the nucleic acid sequences corresponding to the specific “codon usage” used in the organism. The “codon usage” can easily be determined on the basis of computer evaluations of other known genes of the organism in question.

An expression cassette according to the invention is produced by fusion of a suitable promoter with a suitable coding nucleotide sequence and a terminator signal or polyadenylation signal. Common recombination and cloning techniques are used, as described for example in T. Maniatis, E. F. Fritsch and J. Sambrook, Molecular Cloning: A Laboratory Manual, Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y. (1989) and in T. J. Silhavy, M. L. Berman and L. W. Enquist, Experiments with Gene Fusions, Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y. (1984) and in Ausubel, P. M. et al., Current Protocols in Molecular Biology, Greene Publishing Assoc. and Wiley Interscience (1987).

For expression in a suitable host organism, advantageously the recombinant nucleic acid construct or gene construct is inserted into a host-specific vector, which makes optimal expression of the genes in the host possible. Vectors are well known by a person skilled in the art and are given for example in “Cloning vectors” (Pouwels P. H. et al., Ed., Elsevier, Amsterdam-New York-Oxford, 1985).

4. Microorganisms

Depending on the context, the term “microorganism” can mean the wild-type microorganism or a genetically altered, recombinant microorganism or both.

Using the vectors according to the invention, recombinant microorganisms can be produced, which are for example transformed with at least one vector according to the invention and can be used for producing the polypeptides according to the invention. Advantageously, the recombinant constructs according to the invention, described above, are introduced into a suitable host system and expressed. Preferably common cloning and transfection methods, known by a person skilled in the art, are used, for example coprecipitation, protoplast fusion, electroporation, retroviral transfection and the like, for expressing the stated nucleic acids in the respective expression system. Suitable systems are described for example in Current Protocols in Molecular Biology, F. Ausubel et al., Ed., Wiley Interscience, New York 1997, or Sambrook et al. Molecular Cloning: A Laboratory Manual. 2nd edition, Cold Spring Harbor Laboratory, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y., 1989.

In principle, all prokaryotic or eukaryotic organisms may be considered as recombinant host organisms for the nucleic acid according to the invention or the nucleic acid construct. Advantageously, microorganisms such as bacteria, fungi or yeasts are used as host organisms. Advantageously, gram-positive or gram-negative bacteria are used, preferably bacteria of the families Enterobacteriaceae, Pseudomonadaceae, Rhizobiaceae, Streptomycetaceae or Nocardiaceae, especially preferably bacteria of the genera Escherichia, Pseudomonas, Streptomyces, Nocardia, Burkholderia, Salmonella, Agrobacterium, Clostridium or Rhodococcus. The genus and species Escherichia coli is quite especially preferred. Furthermore, other advantageous bacteria are to be found in the group of alpha-Proteobacteria, beta-Proteobacteria or gamma-Proteobacteria.

The host organism or the host organisms according to the invention preferably contain at least one of the nucleic acid sequences, nucleic acid constructs or vectors described in the present invention, which code for an enzyme with phenylethanol dehydrogenase activity according to the above definition.

Depending on the host organism, the organisms used in the method according to the invention are grown or cultured in a manner known by a person skilled in the art. Microorganisms are as a rule grown in a liquid medium, which contains a carbon source generally in the form of sugars, a nitrogen source generally in the form of organic nitrogen sources such as yeast extract or salts such as ammonium sulfate, trace elements such as iron, manganese and magnesium salts and optionally vitamins, at temperatures between 0° C. and 100° C., preferably between 10° C. to 60° C. with oxygen aeration. The pH of the liquid nutrient can be kept at a fixed value, i.e. regulated or not during culture, Culture can be batchwise, semi-batchwise or continuous. Nutrients can be present at the beginning of fermentation or can be supplied later, semicontinuously or continuously.

5. Recombinant Production of Enzymes According to the Invention

The invention further relates to methods for recombinant production of polypeptides according to the invention or functional, biologically active fragments thereof, wherein a polypeptide-producing microorganism is cultured, optionally the expression of the polypeptides is induced and these are isolated from the culture. The polypeptides can also be produced in this way on an industrial scale, if desired.

The microorganisms produced according to the invention can be cultured continuously or discontinuously in the batch method or in the fed-batch method or repeated fed-batch method. A summary of known cultivation methods can be found in the textbook by Chmiel (Bioprozesstechnik 1, Einführung in die Bioverfahrenstechnik [Bioprocess technology 1. Introduction to bioprocess technology] (Gustav Fischer Verlag, Stuttgart, 1991)) or in the textbook by Storhas (Bioreaktoren und periphere Einrichtungen [Bioreactors and peripheral equipment] (Vieweg Verlag, Braunschweig/Wiesbaden, 1994)).

The culture medium to be used must suitably meet the requirements of the respective strains. Descriptions of culture media for various microorganisms are given in the manual “Manual of Methods for General Bacteriology” of the American Society for Bacteriology (Washington D.C., USA, 1981).

These media usable according to the invention usually comprise one or more carbon sources, nitrogen sources, inorganic salts, vitamins and/or trace elements.

Preferred carbon sources are sugars, such as mono-, di- or polysaccharides. Very good carbon sources are for example glucose, fructose, mannose, galactose, ribose, sorbose, ribulose, lactose, maltose, sucrose, raffinose, starch or cellulose. Sugars can also be added to the media via complex compounds, such as molasses, or other by-products of sugar refining. It can also be advantageous to add mixtures of different carbon sources. Other possible carbon sources are oils and fats, for example soybean oil, sunflower oil, peanut oil and coconut oil, fatty acids, for example palmitic acid, stearic acid or linoleic acid, alcohols, for example glycerol, methanol or ethanol and organic acids, for example acetic acid or lactic acid.

Nitrogen sources are usually organic or inorganic nitrogen compounds or materials that contain these compounds. Examples of nitrogen sources comprise ammonia gas or ammonium salts, such as ammonium sulfate, ammonium chloride, ammonium phosphate, ammonium carbonate or ammonium nitrate, nitrates, urea, amino acids or complex nitrogen sources, such as corn-steep liquor, soya flour, soya protein, yeast extract, meat extract and others. The nitrogen sources can be used alone or as a mixture.

Inorganic salt compounds that can be present in the media comprise the chloride, phosphorus or sulfate salts of calcium, magnesium, sodium, cobalt, molybdenum, potassium, manganese, zinc, copper and iron.

Inorganic sulfur-containing compounds, for example sulfates, sulfites, dithionites, tetrathionates, thiosulfates, sulfides, as well as organic sulfur compounds, such as mercaptans and thiols, can be used as the sulfur source.

Phosphoric acid, potassium dihydrogen phosphate or dipotassium hydrogen phosphate or the corresponding sodium-containing salts can be used as the phosphorus source.

Chelating agents can be added to the medium, in order to keep the metal ions in solution. Especially suitable chelating agents comprise dihydroxyphenols, such as catechol or protocatechuate, or organic acids, such as citric acid.

The fermentation media used according to the invention usually also contain other growth factors, such as vitamins or growth promoters, which include for example biotin, riboflavin, thiamine, folic acid, nicotinic acid, pantothenate and pyridoxine. Growth factors and salts often originate from the components of complex media, such as yeast extract, molasses, corn-steep liquor and the like. Moreover, suitable precursors can be added to the culture medium. The exact composition of the compounds in the medium is strongly dependent on the respective experiment and is decided for each specific case individually. Information on media optimization can be found in the textbook “Applied Microbiol. Physiology, A Practical Approach” (Ed, P. M. Rhodes, P. F. Stanbury, IRL Press (1997) p. 53-73. ISBN 0 19 963577 3), Growth media can also be obtained from commercial suppliers, such as Standard 1 (Merck) or BHI (brain heart infusion, DIFCO) and the like.

All components of the medium are sterilized, either by heat (20 min at 1.5 bar and 121° C.) or by sterile filtration. The components can either be sterilized together, or separately if necessary. All components of the medium can be present at the start of culture or can be added either continuously or batchwise.

The culture temperature is normally between 15° C. and 45° C., preferably 25° C. to 40° C. and can be varied or kept constant during the experiment. The pH of the medium should be in the range from 5 to 8.5, preferably around 7.0. The pH for growing can be controlled during growing by adding basic compounds such as sodium hydroxide, potassium hydroxide, ammonia or ammonia water or acid compounds such as phosphoric acid or sulfuric acid. Antifoaming agents, for example fatty acid polyglycol esters, can be used for controlling foaming. To maintain the stability of plasmids, suitable selective substances, for example antibiotics, can be added to the medium. To maintain aerobic conditions, oxygen or oxygen-containing gas mixtures, for example ambient air, are fed into the culture. The temperature of the culture is normally in the range from 20° C. to 45° C. The culture is continued until a maximum of the desired product has formed. This target is normally reached within 10 hours to 160 hours.

The fermentation broth is then processed further. Depending on requirements, the biomass can be removed from the fermentation broth completely or partially by separation techniques, for example centrifugation, filtration, decanting or a combination of these methods or can be left in it completely.

the polypeptides are not secreted in the culture medium, the cells can also be lysed and the product can be obtained from the lysate by known methods for isolation of proteins. The cells can optionally be disrupted with high-frequency ultrasound, high pressure, for example in a French press, by osmolysis, by the action of detergents, lytic enzymes or organic solvents, by means of homogenizers or by a combination of several of the aforementioned methods.

The polypeptides can be purified by known chromatographic techniques, such as molecular sieve chromatography (gel filtration), such as Q-sepharose chromatography, on exchange chromatography and hydrophobic chromatography, and with other usual techniques such as ultrafiltration, crystallization, salting-out, dialysis and native gel electrophoresis. Suitable methods are described for example in Cooper, T. G., Biochemische Arbeitsmethoden [Biochemical processes], Verlag Walter de Gruyter, Berlin, New York or in Scopes, R., Protein Purification, Springer Verlag, New York, Heidelberg, Berlin.

For isolating the recombinant protein, it can be advantageous to use vector systems or oligonucleotides, which lengthen the cDNA by defined nucleotide sequences and therefore code for altered polypeptides or fusion proteins, which for example serve for easier purification. Suitable modifications of this type are for example so-called “tags” functioning as anchors, for example the modification known as hexa-histidine anchor or epitopes that can be recognized as antigens of antibodies (described for example in Harlow, E. and Lane. D., 1988, Antibodies: A Laboratory Manual. Cold Spring Harbor (N.Y.) Press). These anchors can serve for attaching the proteins to a solid carrier, for example a polymer matrix, which can for example be used as packing in a chromatography column, or can be used on a microtiter plate or on some other carrier.

At the same time these anchors can also be used for recognition of the proteins. For recognition of the proteins, it is moreover also possible to use usual markers, such as fluorescent dyes, enzyme markers, which form a detectable reaction product after reaction with a substrate, or radioactive markers, alone or in combination with the anchors for derivatization of the proteins.

For the expression of mutants according to the invention, reference may be made to the description of expression of the wild-type enzyme EbN1 and the expression systems usable for this in WO2005/108590 and WO2006/094945, to which reference is hereby expressly made.

6. Enzyme Immobilization

The enzymes according to the invention can be used free or immobilized in the method described herein. An immobilized enzyme is an enzyme that is fixed to an inert carrier. Suitable carrier materials and the enzymes immobilized thereon are known from EP-A-1149849. EP-A-1 069 183 and DE-OS 100193773 and from the references cited therein. Reference is made in this respect to the disclosure of these documents in their entirety. Suitable carrier materials include for example clays, clay minerals, such as kaolinite, diatomaceous earth, perlite, silica, aluminum oxide, sodium carbonate, calcium carbonate, cellulose powder, anion exchanger materials, synthetic polymers, such as polystyrene, acrylic resins, phenol formaldehyde resins, polyurethanes and polyolefins, such as polyethylene and polypropylene. For making the supported enzymes, the carrier materials are usually employed in a finely-divided, particulate form, porous forms being preferred. The particle size of the carrier material is usually not more than 5 mm, in particular not more than 2 mm (particle-size distribution curve). Similarly, when using dehydrogenase as whole-cell catalyst, a free or immobilized form can be selected. Carrier materials are e.g. Ca-alginate, and carrageenan. Enzymes as well as cells can also be crosslinked directly with glutaraldehyde (cross-linking to CLEAs). Corresponding and other immobilization techniques are described for example in J. Lalonde and A. Margolin “Immobilization of Enzymes” in K. Drauz and H. Waldmann, Enzyme Catalysis in Organic Synthesis 2002, Vol. III, 991-1032, Weinheim. Further information on biotransformations and bioreactors for carrying out methods according to the invention are also given for example in Rehm et al. (Ed.) Biotechnology, 2nd Edn, Vol 3, Chapter 17, VCH, Weinheim.

7. Enzymatic Cyclization of Terpenes 7.1 General Description

In particular, the method of cyclization according to the invention is carried out in the presence of an enzyme, wherein the enzyme is encoded by a nucleic acid sequence according to SEQ ID NO: 1 or a functional equivalent thereof, wherein the nucleic acid sequence is a constituent of a gene construct or vector. Said gene constructs or vectors are described in detail in international application PCT/EP2010/057696 on pages 16 to 20, to which reference is expressly made here. Said functional equivalents, in particular those with citronellal-isopulegol cyclase activity, comprise in particular an F486 or F486-analog mutation, as defined herein.

The host cell, which contains a gene construct or a vector, in which the nucleic acid sequence is contained that codes for the enzyme with the desired activity, is also designated as transgenic organism. The production of said transgenic organisms is known in principle and is discussed for example in international application PCT/EP2010/057696 on page 20, to which reference is expressly made here.

Cells from the group comprising bacteria, cyanobacteria, fungi and yeasts are preferably selected as transgenic organisms. The cell is preferably selected from fungi of the genus Pichia or bacteria of the genera Escherichia, Corynebacterium, Ralstonia, Clostridium, Pseudomonas, Bacillus, Zymomonas, Rhodobacter, Streptomyces, Burkholderia, Lactobacillus or Lactococcus. Especially preferably, the cell is selected from bacteria of the species Escherichia coli, Pseudomonas putida, Burkholderia glumae, Streptomyces lividans, Streptomyces coelicolor or Zymomonas mobilis.

A method according to the invention is preferred, characterized in that the enzyme with the activity of a citronellal-isopulegol cyclase is encoded by a gene that was isolated from a microorganism, selected from Zymomonas mobilis, Methylococcus capsulatus, Rhodopseudomonas palustris, Bradyrhizobium japonicum, Frankia spec, Streptomyces coelicolor and Acetobacter pasteurianus. The relevant genes isolated from Zymomonas mobilis, Streptomyces coelicolor, Bradyrhizobium japonicum and Acetobacter pasteurianus should be mentioned in particular.

A method according to the invention is further preferred, characterized in that the enzyme with cyclase activity was generated by a microorganism that overproduces the enzyme and that was selected from the group of microorganisms comprising the genera Escherichia, Corynebacterium, Ralstonia, Clostridium, Pseudomonas, Bacillus, Zymomonas, Rhodobacter, Streptomyces, Burkholderia, Lactobacillus and Lactococcus.

In particular, a method according to the invention should be mentioned that is characterized in that the enzyme with cyclase activity was produced by transgenic microorganisms of the species Escherichia coli, Pseudomonas putida, Burkholderia glumae, Corynebacterium glutamicum, Saccharomyces cerevisiae, Pichia pastoris, Streptomyces Streptomyces coelicolor, Bacillus subtilis or Zymomonas mobilis, which overproduce the enzyme with cyclase activity.

Further embodiments for carrying out the biocatalytic cyclization method according to the invention, such as, for example, the method for production of isopulegol:

The method according to the invention is characterized in that the enzyme is in at least one of the following forms:

-   -   a) free, optionally purified or partially purified polypeptide;     -   b) immobilized polypeptide;     -   c) polypeptide isolated from cells according to a) or b);     -   d) whole cell, optionally dormant or growing cells, comprising         at least one such polypeptide;     -   e) lysate or homogenizate of the cell according to d).

Another embodiment of the method according to the invention is characterized in that the cells are microorganisms, preferably transgenic microorganisms expressing at least one heterologous nucleic acid molecule coding for a polypeptide with the cyclase activity.

A preferred embodiment of the method according to the invention comprises at least the following steps a), b) and d):

-   a) isolating or recombinantly producing a microorganism producing an     enzyme with cyclase activity from a natural source or, -   b) multiplying this microorganism, -   c) optionally isolating the enzyme with cyclase activity from the     microorganism or preparing a protein fraction comprising said     enzyme, and -   d) transferring the microorganism according to stage b) or the     enzyme according to stage c) to a medium that contains substrate,     e.g. citronellal of general formula (I).

In the method according to the invention, substrate, such as, for example, citronellal is contacted with the enzyme, that has the activity of a citronellal-isopulegol cyclase, in a medium and/or is incubated so that conversion of the substrate, such as, for example, of citronellal, to isopulegol, takes place in the presence of the enzyme. Preferably the medium is an aqueous reaction medium.

The pH of the aqueous reaction medium in which the method according to the invention is preferably carried out is advantageously maintained between pH 4 and 12, preferably between pH 4.5 and 9, especially preferably between pH 5 and 8.

The aqueous reaction media are preferably buffered solutions, which as a rule have a pH of preferably from 5 to 8. The buffer used can be a citrate, phosphate, TRIS (Tris(hydroxymethyl)-aminomethane) or MES buffer (2-(N-morpholino)ethanesulfonic acid). Moreover, the reaction medium can contain other additives, for example detergents (for example taurodeoxycholate).

The substrate, such as, for example, citronellal, is used preferably in a concentration of 2-200 mM, especially preferably 5-25 mM in the enzymatic reaction and can be supplied continuously or discontinuously.

As a rule the enzymatic cyclization takes place at a reaction temperature below the deactivation temperature of the enzyme used and above −10° C. Preferably the method according to the invention is carried out at a temperature between 0° C. and 95° C., especially preferably at a temperature between 15° C. and 60° C., in particular between 20 and 40° C., e.g. at about 25 to 30° C.

A method according to the invention in which the reaction of citronellal isopulegol takes place at a temperature in the range from 20 to 40° C. and/or a pH in the range from 4 to 8 is especially preferred.

As well as these single-phase aqueous systems, in another variant of the invention, two-phase systems are also used. Then, as well as an aqueous phase, organic, non-water-miscible reaction media are used as the second phase. As a result, the reaction products accumulate in the organic phase. After the reaction, the product, such as, for example, isopulegol, in the organic phase can easily be separated from the aqueous phase that comprises the biocatalyst.

A method according to the invention is preferred wherein the production of isopulegol takes place in single-phase aqueous systems or in two-phase systems.

The reaction product isopulegol can be extracted with organic solvents and optionally can be distilled for purification.

Suitable organic solvents are for example aliphatic hydrocarbons, preferably with 5 to 8 carbon atoms, such as pentane, cyclopentane, hexane, cyclohexane, heptane, octane or cyclooctane, halogenated aliphatic hydrocarbons, preferably with one or two carbon atoms, such as dichloromethane, chloroform, carbon tetrachloride, dichloroethane or tetrachloroethane, aromatic hydrocarbons, such as benzene, toluene, the xylenes, chlorobenzene or dichlorobenzene, aliphatic acyclic and cyclic ethers or alcohols, preferably with 4 to 8 carbon atoms, such as ethanol, isopropanol, diethyl ether, methyl-tert-butyl ether, ethyl-tert-butyl ether, dipropyl ether, diisopropyl ether, dibutyl ether, tetrahydrofuran or esters such as ethyl acetate or n-butyl acetate or ketones such as methyl isobutyl ketone or dioxane or mixtures thereof. Especially preferably, the aforementioned heptane, methyl-tert-butyl ether, diisopropyl ether, tetrahydrofuran, and ethyl acetate are used.

The cyclases used according to the invention can be used in the method according to the invention as free or immobilized enzyme, as already described above.

For the method according to the invention it is possible to use dormant or growing, free or immobilized cells, which contain nucleic acids, nucleic acid constructs or vectors coding for the cyclase. Lysed cells, such as cell lysates or cell homogenates can also be used. Lysed cells are for example cells that have been permeabilized by a treatment for example with solvents, or cells that have been disrupted by an enzyme treatment, by a mechanical treatment (e.g. French press or ultrasound) or by some other method. The resultant raw extracts are advantageously suitable for the method according to the invention. Purified or partially purified enzymes can also be used for the method.

Where tree organisms or enzymes are used for the method according to the invention, they are usefully isolated, via a filtration or centrifugation, for example, prior to the extraction.

The method according to the invention can be operated batchwise, semibatchise or continuously.

7.2. Enzymatic Cyclization of Citronellal

The citronellal of formula (II) used in accordance with the invention, and converted by means of an enzyme having citronellal-isopulegol cyclase activity, is available commercially both as (+)-R-citronellal of the formula (R-II) and as (−)-S-citronellal of the formula (S-II), and as a racemate of the formula (II).

The isopulegol formed in accordance with the invention, of formula (I)

has a stereocenter in each of positions 1, 3 and 6, and so in principle there are 4 different diastereomers each with 2 enantiomers conceivable, in other words a total of 8 stereomers, if the starting point is the racemate of the citronellal of formula (I).

Suitable enzymes having the activity of a citronellal-isopulegol cyclase are intramolecular transferases from the subclass of the isomerases; that is, proteins having the enzyme code EC 5.4 (enzyme code in accordance with Eur. J. Biochem. 1999, 264, 610-650). Preferably they are representatives having the enzyme code 54.99A 7. Also suitable in particular as enzymes having the activity of citronellal-isopulegol cyclase are those cyclases which also bring about the cyclization of homofarnesol to ambroxan or of squalene to hopene, which are described exhaustively in international application PCT/EP2010/057696, hereby incorporated by reference; the enzymes and mutants described here are also suitable.

One particularly suitable embodiment of the method according to the invention is that wherein the enzyme used in the method according to the invention and having the activity of a citronellal-isopulegol cyclase possesses a polypeptide sequence which either

-   a) is SEQ ID NO: 2, or -   b) in which up to 25% of the amino acid residues are altered     relative to SEQ ID NO: 2 by deletion, insertion, substitution or a     combination thereof, and which still has at least 50% of the     enzymatic activity of SEQ ID NO: 2.

Suitable enzymes with citronellal-isopulegol cyclase activity and comprising an amino sequence according to SEQ ID NO: 2, and also “functional equivalents” or analogs of the specifically disclosed enzymes (E) having citronellal-isopulegol cyclase activity, are described, as already indicated above, exhaustively in the international application PCT/EP2010/057696, hereby incorporated by reference.

In one particularly preferred embodiment of the method, the enzyme having citronellal-isopulegol cyclase activity is selected from enzymes which comprise an amino acid sequence according to SEQ ID NO: 2 or a sequence derived therefrom in which up to 25%, preferably up to 20%, more preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2, 1% of the amino acid residues have been altered by a deletion, a substitution, an insertion or a combination of deletion, substitution and insertion, the polypeptide sequences altered relative to SEQ ID NO: 2 still possessing at least 50%, preferably 65%, more preferably 80%, more particularly more than 90% of the enzymatic activity of SEQ ID NO: 2. In this context, enzymatic activity of SEQ ID NO: 2 refers to the capacity to effect biocatalytic cyclization of citronellal of general formula (II) to the corresponding isopulegol of formula (I).

The method according to the invention is carried out preferably in the presence of an enzyme, the enzyme being encoded by a nucleic acid sequence according to SEQ ID NO: 1 or a functional equivalent thereof.

Functional equivalents here describe in principle nucleic acid sequences which under standard conditions undergo hybridization with a nucleic acid sequence or parts of a nucleic acid sequence and are capable of bringing about the expression of a protein having the same properties as those of the enzyme having citronellal-isopulegol cyclase activity in a cell or in an organism.

A functional equivalent is additionally understood to refer to nucleic acid sequences which are homologous or identical to a defined percentage with a particular nucleic acid sequence (“original nucleic acid sequence”) and have the same activity as the original nucleic acid sequences, and also, in particular, natural or artificial mutations of these nucleic acid sequences.

The nucleic acid sequences which can be used for encoding the enzymes having citronellal-isopulegol cyclase activity that can be used in the method according to the invention are likewise described exhaustively in international application PCT/EP2010/057696, hereby incorporated by reference.

With particular preference the method according to the invention is carried out in the presence of an enzyme, the enzyme being encoded by a nucleic acid sequence according to SEQ ID NO: 1 or a functional equivalent thereof, the nucleic acid sequence being part of a gene construct or vector. Such gene constructs or vectors are described exhaustively in international application PCT/EP2010/057696 on pages 16 to 20, hereby incorporated by reference.

With very particular preference the method according to the invention is carried out in the presence of an enzyme, where the enzyme is encoded by a nucleic acid sequence according to SEQ ID NO: 1 or a functional equivalent thereof, the nucleic acid sequence being part of a gene construct or vector which are present in a host cell.

The host cell which comprises a gene construct or a vector in which the nucleic acid sequence is present that encodes the enzyme having the citronellal-isopulegol cyclase activity is also referred to as a transgenic organism. The production of such transgenic organisms is known in principle and is discussed, for example, in international application PCT/EP2010/057696 on page 20, hereby incorporated by reference.

Transgenic organisms selected are preferably cells from the group consisting of bacteria, cyanobacteria, fungi and yeasts. The cell is preferably selected from fungi of the genus Pichia or bacteria of the genera Escherichia, Corynebacterium, Ralstonia, Clostridium, Pseudomonas, Zymomanas, Rhodobacter, Streptomyces, Burkholderia, Lactobacillus or Lactococcus. With particular preference the cell is selected from bacteria of the species Escherichia coli, Pseudomonas putida, Burkholderia glumae, Streptomyces lividans, Streptomyces coelicolor or Zymomonas mobilis.

A preferred method according to the invention is that wherein the enzyme having the activity of a citronellal-isopulegol cyclase is encoded by a gene which has been isolated from a microorganism selected from the group of microorganisms consisting of Zymomonas mobilis, Methylococcus capsulatus, Rhodopseudomonas palustris, Bradyrhizobium japonicum, Frankia spec. and Streptomyces coelicolor. With particular preference the gene in question has been isolated from Zymomonas mobilis.

Preferred furthermore is a method according to the invention wherein the enzyme having the activity of a citronellal-isopulegol cyclase has been produced by a microorganism which overproduces the enzyme having the activity of a citronellal-isopulegol cyclase and which has been selected from the group of microorganisms consisting of the genera Escherichia, Corynebacterium, Ralstonia, Clostridium, Pseudomonas, Bacillus, Zymomonas, Rhodobacter, Streptomyces, Burkholderia, Lactobacillus and Lactococcus.

A particularly preferred method according to the invention is that wherein the enzyme having the activity of a citronellal-isopulegol cyclase has been produced by transgenic microorganisms of the species Escherichia coli, Pseudomonas putida, Burkholderia glumae, Corynebacterium glutamicum, Saccharomyces cerevisiae, Pichia pastoris, Streptomyces Streptomyces coelicolor, Bacillus subtilis or Zymomonas mobilis which overproduce the enzyme having the activity of a citronellal-isopulegol cyclase.

The above-described further embodiments for carrying out the biocatalytic method according to the invention for cyclizing terpenes apply correspondingly in respect of the production of isopulegol.

A further subject of the present invention is also the use of an enzyme having the activity of a citronellal-isopulegol cyclase for the biocatalytic conversion of citronellal to isopulegol.

Preference is given to the use of an enzyme having the activity of a citronellal-isopulegol cyclase for the biocatalytic conversion of citronellal to isopulegol, wherein the enzyme possesses a polypeptide sequence which either

-   a) is SEQ ID NO: 2, or -   b) in which up to 25% of the amino acid residues are altered     relative to SEQ ID NO: 2 by deletion, insertion, substitution or a     combination thereof, and which still has at least 50% of the     enzymatic activity of SEQ ID NO: 2.

Also preferred is the use of an enzyme having the activity of a citronellal-isopulegol cyclase for the biocatalytic conversion of citronellal to isopulegol, wherein the enzyme is encoded by a nucleic acid sequence according to SEQ ID NO: 1 or a functional equivalent thereof.

A further subject of the present invention is also the use of a gene construct or vector comprising a nucleic acid sequence according to SEQ ID NO: 1 or a functional equivalent thereof which encode a polypeptide having the activity of a citronellal-isopulegol cyclase which serves the biocatalytic conversion of citronellal to isopulegol in a method of production of isopulegol by cyclization citronellal.

Likewise a further subject of the present invention is the use, as well, of a host cell which comprises a gene construct or a vector comprising a nucleic acid sequence according to SEQ ID NO: 1 or a functional equivalent thereof for producing an enzyme having the activity of a citronellal-isopulegol cyclase for the biocatalytic conversion of citronellal isopulegol.

The method described above opens up for the first time. The possibility of cyclizing citronellal to isopulegol by means of an enzyme.

8. Methods of Production of Menthol

The isopulegol prepared inventively can be converted into menthol by catalytic hydrogenation in a conventional way. Suitable for this purpose, as well as conventional hydrogenation processes, is, in particular, a catalytic method, as described in WO 2009/013192.

The method according to the invention is implemented in particular using catalysts comprising

-   -   45% to 55% by weight of oxygen-containing compounds of nickel,         calculated as NiO,     -   25% to 35% by weight of oxygen-containing compounds of         zirconium, calculated as ZrO₂,     -   5% to 20% by weight of oxygen-containing compounds of copper,         calculated as CuO,     -   1% to 3% by weight of oxygen-containing compounds of molybdenum,         calculated as MoO₃, and     -   0% to 5% by weight of further components,         the figures in % by weight adding up to 100% by weight and         relating to the dry, unreduced catalyst.

One particularly preferred catalyst is composed of 49% to 53% by weight of NiO, 15% to 19% by weight of CoO, 28% to 32% by weight of ZrO₂ and 1% to 2% by weight of MoO₃ and also, optionally, 0% to 3% by weight of further components such as graphite, for example, the respectively selected weight fractions of the individual components being based on the dry, unreduced catalyst and adding up to 100% by weight. Catalysts of this kind are known and can be produced for example as described in EP 0 696 572 or in WO 2009/013192.

In general the catalysts are used preferably in the form of unsupported catalyst. The term “unsupported catalyst” refers to a catalyst which in contrast to a supported catalyst is composed only of catalytically active material. Unsupported catalysts can be used by introducing the catalytically active material, ground to a powder, into the reaction vessel, or by disposing the catalytically active material in the reactor after grinding, mixing with shaping aids, shaping and heat-treating in the form of shaped catalyst bodies—for example, as spheres, cylinders, tablets, rings, coils, strands and the like.

In the context of one preferred embodiment of the hydrogenation method according to the invention, the selected heterogeneous catalyst is employed in the form of a fixed-bed catalyst.

To implement the method according to the invention, the isopulegol starting material as described above is contacted with hydrogen and with the selected catalyst. The hydrogen here may be used in undiluted form, typically in a purity of about 99.9% by volume, or in diluted form, i.e. in the form of mixtures with inert gases such as nitrogen or argon, for example. It is preferred to use hydrogen in undiluted form. The reaction can be carried out successfully without adding solvent or in the presence of organic solvents which are inert under the reaction conditions, such as, for example, methanol, ethanol, isopropanol, hexane, heptane, cyclohexane and the like. It is preferred to carry out the reaction without adding solvent.

The hydrogenation of isopulegol in accordance with the invention can be carried out under a hydrogen pressure (absolute) in the range from 1 to 200 bar, such as from 2 or 3 to 200 bar, in particular from 4 or 5 to 150 bar, such as from 5 to 100 bar, or in the range from 5 to 50 bar. As a reaction temperature for implementing the hydrogenation according to the invention, a temperature is selected, advantageously, that is in the range from 20 to 150° C., such as from 40 to 130° C., or from 60 to 110° C. and more particularly from 70 to 100° C.

The practical approach to the implementation is generally to supply the isopulegol for conversion to the catalyst, which is typically located in a fixed bed reactor heated, in particular, from the outside, such as a tube reactor, autoclave or tube-bundle reactor, for example, at the desired reaction temperature and under the desired pressure. The velocity over the catalyst in this case is generally 0.1 to 1.0, such as 0.1 to 0.6 or 0.2 to 0.4, kg of isopulegol per kg of catalyst per hour. In this context it may be useful to heat the isopulegol that is to be used, even before it is supplied to the reaction vessel or to the reactor, this heating being preferably to reaction temperature.

The reactor can be operated either in liquid phase mode or in trickle mode—that is, the starting materials may be passed through the reactor either from bottom to top or from top to bottom. The hydrogenation method of the invention can be carried out either batchwise or continuously. In both cases, unreacted starting material can be circulated together with the hydrogen.

The hydrogenation according to the invention may also be carried out in stages in a cascade of two or more reactors, i.e. 2 to in general 4, such as 2 or 3, for example, reactors connected in series, preferably fixed bed reactors. In this case, in the first reactor, typically referred to as the main reactor, the main conversion of the reaction is achieved under the reaction conditions described above, and the crude product obtained is passed to a second reactor, typically referred to as secondary reactor, in which the as yet unreacted starting material is at least largely converted inventively into L-menthol. The reaction conditions here may be selected, independently of one another, preferably in the ranges stated above.

The method of the invention can be carried out batchwise, semibatchwise or continuously. It is preferred to carry out the method continuously, more particularly entirely continuously, in which case the starting materials are introduced continuously into the reactor and the resulting reaction mixture or reaction product is discharged continuously from the reactor. It has further proven advantageous, in view of the position of the melting point of the reaction product according to the invention, namely menthol, especially L-menthol, to provide for heating of the transport lines used.

The method of the invention allows menthol to be produced by catalytic hydrogenation of isopulegol, with typically only a minor degree of formation of unwanted diastereomers of menthol. Accordingly, when using isopulegol with a corresponding purity, the method of the invention yields menthol of the formula (III) in a chemical purity of 97% by weight or more, preferably of 98% to 100% by weight, more preferably of 98.5% to 99.9% by weight, very preferably at least 99% to 99.9% by weight. The term “chemical purity” here also encompasses the diastereomeric purity of the resulting menthol in relation to the diastereomers neoisomenthol of formula (IIIa), neomenthol of formula (IIIb) and isomenthol of formula (IIIc). Accordingly, in the context, the method according to the invention preferably yields menthol having a diastereomeric purity of 97% by weight or more, preferably of 98% to 100% by weight, more preferably of 98.5% to 99.9% by weight and very preferably of at least 99% to 999% by weight.

Where isopulegol is used in optically active form—preferably, in accordance with the invention, mixtures comprising predominantly the Lisopulegol enantiomer—the method product according to the invention that is obtained is generally menthol in optically active form, preferably in the form of (−)- or L-menthol. The hydrogenation according to the invention proceeds generally largely without notable racemization of the material used. Accordingly, according to the enantiomeric excess of the optically active isopulegol used, optically active menthol, preferably L-menthol when using L-isopulegol, is obtained as the product, with an enantiomeric excess (ee) of 80% ee or more, preferably of 85% or 90% ee or more, more preferably of 95% to 100% ee, more preferably of 96% to 99.9% ee, very preferably of 97% to 99.8% ee, even more preferably of 98% to 99.7% ee, and with more particular preference of 98.5% to 99.6% ee.

The menthol obtained according to the invention is notable, furthermore, for a particularly low level of the unwanted by-products menthone of formula (IIId) and isomenthone of formula (IIIe) and neoisomenthol of formula (IIIa).

These by-products are obtained generally, in the context of the method according to the invention, only in a proportion, relative to the amount of menthol obtained, of up to 0.5% by weight, preferably 0.4% by weight, more preferably 0.3% by weight, more particularly 0.2% by weight, and very preferably 0.1% to 0% by weight.

9. Examples of Substrates which can be Used for Enzymatic or Biocatalytic Conversions According to the Invention

The enzymes and microorganisms described herein are especially suitable for converting compounds of the general formula IV above. Non-limiting examples thereof are summarized in table A below, which gives the structural formula and the chemical name.

TABLE A Further substrates Formula

Name

Citral

Neral

Nerol

Nerylacetone

Geranial

Geraniol

Geranylic acid

cis-Geranylic acid

Geranylacetone

Farnesol

Farnesylacetone

Homofarnesylic acid

Homofarnesol

Trimethyl- tridecatetraene

Melonal

Nonadienal

Citronellol

β-Citronellene

Citronellic acid

Hydroxycitronellal

Heptanal

Linalool

Farnesene (β)

Myrcene

Myrcenol

Dihydromyrcenol

Lavandulol

Nerolidol

(E)-β-Ocimene (4 isomers present)

Tagetone

Solanone

2,6,10-Trimethyl- 9-undecanal

The reaction products produced in the conversion of these substrates can be detected and quantified in a conventional way using standard analytical methods, such as chromatography, HPLC, gas chromatography, mass spectrometry, GC/MS n, MALDI-TOF, and combinations thereof.

If nonimmobilized organisms or enzymes are used for the method according to the invention, preferably these are separated prior to extraction, for example by filtration or centrifugation.

The method according to the invention can be operated batchwise, semi-batchwise or continuously.

Experimental Section

In the absence of special information in the examples below, the general information below is taken to apply.

A. GENERAL INFORMATION

All materials and microorganisms used are commercially available products.

Unless stated otherwise, the cloning and expression of recombinant proteins is carried out by standard methods, as described for example in Sambrook, J., Fritsch, E. F. and Maniatis. T., Molecular Cloning: A Laboratory Manual, 2nd edition, Cold Spring Harbor Laboratory, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y., 1989.

a) Bacterial Strains, Plasmids and Growing Conditions

All experiments were carried out with E. coli. The SHC proteins were expressed in E. coli BL21 (DE3) pLysS or E. coli Rosetta pLysRAR62, comprising pET16b constructs with the respective shc gene, by growing in Luria-Bertani medium, supplemented with ampicillin (100 μg/ml), chloramphenicol (34 μg/ml); and 0.5 mM isopropylthio-β-D-galactoside at OD₆₀₀ of 0.4 and additional growth for 4 hours at 30° C.

b) Vector Constructs

The respective squalene-hopene cyclase gene (e.g. Zymomonas mobilis ZMO1548 [NC_(—)006526.2, region: 1578816 . . . 1580993]) was PCR-amplified from chromosomal DNA, using corresponding primer pairs (e.g. ZMO1548-fwd (5′-gcgctgtttcatatgggtattgaca-3′) (SEQ. ID. NO: 327) and ZMO1548-rev (5′-gcgcttaccctggatcctcgaaaat-3′) (SEQ. ID. NO: 328)). The restriction enzyme digested (e.g. with NdeI/BamHI) PCR product was cloned into pET16b, (obtaining e.g.) pET1584. The constructs were verified by DNA sequencing and transformed into E. coli XL1-blue.

The shc-gene from other microorganisms (e.g. from A. acidocaidarius) was cloned similarly.

All plasmids were transformed individually into E. coli BL21 (DE3) pLysS or E. coli Rosetta pLys-RAR62.

c) Cyclization Assay with Various Substrates (Standard Conditions)

Recombinant E. coli cells were suspended in 20 mM Tris-HCl pH 8.0 (3 ml per g moist cells). The cyclization mixture contained 250 μl of cell suspension, 50 μl of 1 M citrate buffer (pH 4.5), 20 mM (final concentration) of substrate and water to 500 μl. In the cyclization of squalene, 1% (v/v) Triton-X100 was added. For the homofarnesol cyclization. E. coli cells (6 g moist cells) were suspended in solubilization buffer (50 mM phosphate, 10 mM MgCl₂ (pH 6.5; total volume: 25 ml). The cells were lysed at 1500 bar using a Manton-Gaulin homogenizer. Insoluble cellular debris was centrifuged off (15 min at 4° C. and 7150*g). The cyclization mixture contained 1 ml raw cell extract and 20 mM homofarnesol in 1.25 ml buffer (50 mM potassium phosphate, 45 mM MgCl₂ (pH 6.5). The reaction mixture was stirred at 30° C. with a magnetic stirrer. The reaction was stopped by extraction with heptane. The organic phase was analyzed by gas chromatography. Controls were carried out with E. coli cells bearing an empty vector and with heat-inactivated SHC-expressing cells. Formation of cyclization products was never observed with the controls (data not shown).

d) Gas Chromatography

Terpenoids were analyzed qualitatively and quantitatively by gas chromatography using an Agilent 7890A gas chromatograph, equipped with a DB-5 column (20 m×0.1 mm×0.1 μm) and an ionization detector. 3 μl of the solvent extract was applied on the column (split ratio 1:5, helium flow rate 0.25 or 0.5 ml/min, injector temperature 250° C.).

To separate linear and cyclic monoterpenoids, the initial furnace temperature (60° C.) was raised to 130° C. at 40° C./min, at 2° C./min to 150° C. and then at 40° C./min to 200° C. The retention times of the terpenoids were as follows: (R, S)-citronellal (755 min), isopulegol (770 min), neo-isopulegol (7.90 min), iso-isopulegol (8.10 min), neoiso-isopulegol (8.25 min), 1-decanol (9.91 min).

For the detection of triterpenes, the injector temperature was set at 300° C. The furnace temperature was initially 60° C., and was increased at 40″C/min to 220° C. and then at 6′C/min to 310° C. and held constant there for 10 min. Squalene and hopene eluted after 19.2 min and 26.9 min respectively.

Homofarnesol and ambroxan were analyzed on a 10 m Optima 1 column (Macherey & Nagel, Düren, Germany). The initial furnace temperature (100° C.) was increased at 5° C./min to 200° C. and held at this temperature for 5 min. Then it was increased at 30° C./min to 320° C. An analysis took 40 min. The retention times were as follows: homofarnesol (10.8 min), ambroxan (9.9 min). As an alternative, a Shimadzu GC-MS OP 2010 system with an FS Supreme 5 column (30 m×0.25 mm×0.25 μm) was used for coupled GC/MS analysis (splitbratio 1:20; 3 min 120° C., increase to 135° C. at 2° C./min and further increase to 365° C. at 10° C./min, followed by cooling to 300° C. at 70° C./min). The GC-MS data were analyzed using LabSolutions GCsolutions Postrun software. It should be noted that the substrates citronellal racemate, (R)-citronellal and (S)-citronellal always contain small amounts of isopulegol and neo-isopulegol as impurities. The GC surface values for these linear terpenoids were established as 100%. The surface values for the isopulegol isomers in the product were corrected by the amount of isopulegol isomer that was already present in the substrate. The standard deviation was calculated on the basis of 24 individual tests using two separately grown E. coli cultures.

B. EXAMPLES Example 1 Production of Mutants of the F486X Type of the Squalene-Hopene Cyclases by Rational Protein Design Using Quick-Change Mutagenesis

The mutants of various squalene-hopene, cyclases were incorporated by means of “quick-change” mutagenesis into the corresponding gene. The procedure based on the manufacturer's information (Agilent Technologies, Waldbronn) was largely followed. First, a FOR was carried out:

FOR charge: 1.8 μl DMSO

-   -   2 μl dNTPs (each 2.5 mM)     -   1.5 μl forward primer (10 pmol/μl)     -   1.5 μl reverse primer (10 pmol/μl)     -   1 μl templates (1 μg/μL; recombinant plasmid bearing SHC gene,         for example pETZmSHC_(—)1)     -   0.2 μl Prime-Star Polymerase (Takara, 2.5 Units/μl)     -   6 μl 5× buffer     -   16 μl H₂O

FOR program:

-   -   (1) 95° C. 3 minutes     -   (2) 95° C. 45 seconds     -   (3) 53° C. 1 minute     -   (4) 68° C. 17 minutes     -   5× repetition of steps (2), (3) and (4)

After the PCR, 10 μl of the charge was digested with the restriction enzyme Dpnl for at least 1 hour at 37° C. Then transformation into E. coli XL1-blue cells was carried out. After DNA sequencing, transformation into the expression strain e.g. E. coli Rosetta pLysRAR62 took place. The gene can also be modified similarly in other expression plasmids.

The following primers were used for the quick-change PCR. The respective exchange is shown printed in bold in the primer names. The genes that are modified by the respective primers are indicated with italics in the primer names; there is the following correspondence:

Primer name Sequence SEQ ID NO ZmSHC_1 F486Ilefor GTTATTATCCTTATCGATGGCTCCCCAACCG 329 ZmSHC_1 F486Ilerev GGTTGGGGAGCCATCGATAAGGATAATAACAG 330 ZmSHC_1 F486Metfor GTTATTATCCTTATCCATGGCTCCCCAACCG 331 ZmSHC_1 F486Metrev GGTTGGGGAGCCATGGATAAGGATAATAACAG 332 ZmSHC_1 F486Thrfor GTTATTATCCTTATCGGTGGCTCCCCAACCG 333 ZmSHC_1 F486Thrrev GGTTGGGGAGCCACCGATAAGGATAATAACAG 334 ZmSHC_1 F486Glnfor GTTATTATCCTTATCCTGGGCTCCCCAACCG 335 ZmSHC_1 F486Glnrev GGTTGGGGAGCCCAGGATAAGGATAATAACAG 336 ZmSHC_1 F486Asnfor GTTATTATCCTTATCGTTGGCTCCCCAACCG 337 ZmSHC_1 F486Asnrev GGTTGGGGAGCCAACGATAAGGATAATAACAG 338 ZmSHC_1 F486Lysfor GTTATTATCCTTATCTTTGGCTCCCCAACCG 339 ZmSHC_1 F486Lysrev GGTTGGGGAGCCAAAGATAAGGATAATAACAG 340 ZmSHC_1 F486Aspfor GTTATTATCCTTATCATCGGCTCCCCAACCG 341 ZmSHC_1 F486Asprev GGTTGGGGAGCCGATGATAAGGATAATAACAG 342 ZmSHC_1 F486Glufor GTTATTATCCTTATCTTCGGCTCCCCAACCG 343 ZmSHC_1 F486Glurev GGTTGGGGAGCCGAAGATAAGGATAATAACAG 344 ZmSHC_1 F486Trpfor GTTATTATCCTTATCCCAGGCTCCCCAACCG 345 ZmSHC_1 F486Trprev GGTTGGGGAGCCTGGGATAAGGATAATAACAG 346 ZmSHC_1 F486Argfor GTTATTATCCTTATCACGGGCTCCCCAACCG 347 ZmSHC_1 F486Argrev GGTTGGGGAGCCCGTGATAAGGATAATAACAG 348 ZmSHC_1 F486Cysfor GTTATTATCCTTATCGCAGGCTCCCCAACCG 349 ZmSHC_1 F486Cysrev GGTTGGGGAGCCTGCGATAAGGATAATAACAG 350 ZmSHC_1 F486Gfor GTTATTATCCTTATCACCGGCTCCCCAACCG 351 ZmSHC_1 F486Grev GGTTGGGGAGCCGGTGATAAGGATAATAACAG 352 ZmSHC_1 F486Sfor GTTATTATCCTTATCGCTGGCTCCCCAACCG 353 ZmSHC_1 F486Srev GGTTGGGGAGCCAGCGATAAGGATAATAACAG 354 ZmSHC_1 F486Pfor GTTATTATCCTTATCCGGGGCTCCCCAACCG 355 ZmSHC_1 F486Prev GGTTGGGGAGCCCCGGATAAGGATAATAACAG 356 ZmSHC_1 F486Hfor GTTATTATCCTTATCATGGGCTCCCCAACCG 357 ZmSHC_1 F486Hrev GGTTGGGGAGCCCATGATAAGGATAATAACAG 358 ZmSHC_1 F486Lfor GTTATTATCCTTATCCAGGGCTCCCCAACCG 359 ZmSHC_1 F486Lrev GGTTGGGGAGCCCTGGATAAGGATAATAACAG 360 ZmSHC_1 F486Vfor GTTATTATCCTTATCAACGGCTCCCCAACCG 361 ZmSHC_1 F486Vrev GGTTGGGGAGCCGTTGATAAGGATAATAACAG 362 ZmSHC_1 F486Afor GTTATTATCCTTATCCGCGGCTCCCCAACCG 363 ZmSHC_1 F486Arev GGTTGGGGAGCCGCGGATAAGGATAATAACAG 364 ZmSHC_1 F486Yfor GTTATTATCCTTATCATAGGCTCCCCAACCG 365 ZmSHC_1 F486Yrev GGTTGGGGAGCCTATGATAAGGATAATAACAG 366 ZmSHC_1 Y702Cfor GCCGATAAAAATCGCAACGCAGCATAAACG 367 ZmSHC_1 Y702Crev CGTTTATGCTGCGTTGCGATTTTTATCGGC 368 ZmSHC_1 Y702Ffor GCCGATAAAAATCTTTACGCAGCATAAACG 369 ZmSHC_1 Y702Frev CGTTTATGCTGCGTAAAGATTTTTATCGGC 370 ZmSHC_1 Y702Afor GCCGATAAAAATCCGCACGCAGCATAAACG 371 ZmSHC_1 Y702Arev CGTTTATGCTGCGTGCGGATTTTTATCGGC 372 ZmSHC_1 Y702Sfor GCCGATAAAAATCGCTACGCAGCATAAACG 373 ZmSHC_1 Y702Srev CGTTTATGCTGCGTAGCGATTTTTATCGGC 374 ZmSHC_1 Y561Afor GAACCGCACCGGTGCCATAGATCGCATTAACG 375 ZmSHC_1 Y561Arev GGTTTGGTCGTTGGGGCGTTAATGCGATCTATGG 376 ZmSHC_1 Y705Afor CCATAATCGGGAAGAATTGCCGCGCAAAATC 377 ZmSHC_1 Y705Arev CTGCGTTATGATTTTGCGCGGCAATTCTTC 378 ZmSHC_2 F486Cfor GGCGGTTGGGGCGCTTGCGATGCCAATAACAG 379 ZmSHC_2 F486Crev CTGTTATTGGCATCGCAAGCGCCCCAACCGCC 380 Ap F486Crev CATTATCTTTATCGCATGCACCCCAACCACC 381 Ap F486Cfor GGTGGTTGGGGTGCATGCGATAAAGATAATG 382 Bj F486Cfor CGGCTGGGGCGCGTGCGATAAAGATAAC 383 Bj F486Crev GTTATCTTTATCGCACGCGCCCCAGCCG 384 Sc F486Cfor CGGCGCCTGGGGCGCCTGCGACGTCGACAAC 385 Sc F486Crev GTTGTCGACGTCGCAGGCGCCCCAGGCGCCG 386 ZmSHC_1 SEQ ID NO: 2; ZmSHC_2 SEQ ID NO: 6; Ap SEQ ID NO: 4; Bj SEQ ID NO: 5 and Sc SEQ ID NO: 3.

Example 2 Activity Tests with Mutants of Squalene-hopene Cyclase-1 (SHC-1) from Zymomonas mobilis

The influence of various single mutations, produced according to example 1, in the sequence position corresponding to F486, on the cyclase activity was determined for various substrates.

a) Citronellal

After the general detection of a slight cyclization activity of the squalene-hopene cyclase-1 from Zymomonas mobilis (SEQ ID NO:2) with respect to citronellal, the turnover rate was greatly improved by rational protein design. Exchange of the phenylalanine residue F486 for alanine led in preliminary tests (cf. FIG. 2) to a greatly increased production of isopulegol (2) starting from citronellal (1).

The increased activity of the SHC_(—)1-F486A mutant was then investigated in more detail. In addition to a for better conversion of the citronellal substrate, it was also found that this prefers the R(+) isomer as substrate and compared with the WT it is also converted in a much shorter time (cf. FIG. 2). Whereas with the \NT enzyme the reaction with R(+)-citronellal is not measurable until after quite long incubation, the F486A mutant shows high conversions, in particular at the start of the reaction. This effect is not observed with SH-citronellal as substrate. It is notable that the F486A mutant only forms isopulegol I and II, whatever the stereoconfiguration of the substrate. The WT, in contrast, is dependent on the stereoconfiguration of the substrate and forms, as well as isopulegol I, mainly isopulegol II from R(+)-citronellal and almost exclusively isopulegol III from S(−)-citronellal.

Based on these results, in further experiments the importance of the amino acid residues at position 486 was investigated more closely. For this, by means of mutagenesis, the phenylalanine residue was exchanged against each further amino acid and the activity of the various muteins was tested with citronellal as substrate (for sequences see FIGS. 1 a and b). It was found that some amino acids at this position not only improve the conversion of citronellal by the enzyme, but additionally lead to higher product specificity in the reaction, so that fewer isomers of isopulegol are produced (see FIG. 3).

Exchange for arginine, proline and lysine leads to a loss in activity with respect to citronellal. The amounts of product determined also occur, in the same distribution, as contamination in the negative control (‘K’ see FIG. 3). The highest activity was observed after exchange for valine, threonine, cysteine, isoleucine and alanine. Overall, the altered product spectrum of some muteins is notable. Not all show the formation of three isopulegol peaks as the wild type as well as the quantitative distribution differs.

There are altogether 2³ isopulegol isomers:

Until now, the main product (isopulegol I) has been assigned to the enantiomeric pair (1R,3R,6S)—isopulegol or (1S,3S,6R)-isopulegol.

The highest yield of isopulegol with the least by-products (consisting of further isomers) accompanied by high enzyme activity is displayed by the Zm-SHC-1 F486C mutant.

b) Squalene

Clear changes in activity after mutation at position F486 are also seen with squalene as substrate. Interestingly, in this case the exchange of phenylalanine for tyrosine produces almost a doubling of the conversion (see FIG. 4).

Example 3 Activity Tests with Mutants of Other Squalene-Hopene Cyclases

The influence of various single mutations, produced according to example 1, in the sequence position corresponding to F486 on the cyclase activity of various other SHCs was determined for various citronellal substrates (in each case 20 mM overnight incubation):

The mutants are as follows:

Ap-SHC: F481C,

EU-SHC: F447C,

Sc-SHC: F449C,

Zm SHC-2: F438C

The phenylalanine residues are located in positions that are analogous to the F486 of Zm-SHC-1 (SEQ ID NO:2).

The results can be seen in FIG. 5 (citronellal racemate as substrate), FIG. 6 (R(+)-citronellal as substrate), and FIG. 7 (S(−)-citronellal as substrate). The control was a charge without active biocatalyst.

It can be seen that the wild-type enzymes, through mutation at the stated position corresponding to F486 (of Zm SHC-1), can now cyclize citronellal to isopulegol and moreover convert the R(+) form with increased selectivity compared with the S(−) form.

Example 4 Conversion of Compounds of Formula IV

These substances were converted under conditions corresponding to those employed for the conversion of citronellal as described above.

Example 5 Isolation and Characterization of the Squalene-Hopene Cyclase from Zymomonas mobilis (Zm-SHC)

Iinternational application PCT/EP2010/057696, hereby incorporated by reference, describes how, using specific oligonucleoticles, the Zm-SHC gene from the genomic DNA of Zymomonas mobilis was amplified and expressed in Escherichia coli.

a) Material and Methods:

Addressed below are only materials and methods not mentioned in this form in international application PCT/EP2010/057696.

b) Strains, Plasmids and Culture Conditions:

The E. coli strain DH5α, the E. coli strain BL21 (DE3)pLysS (Novagen) and the E. coli Rosetta strain were used. The plasmid pET16b (Novagen) was used for cloning. For the overexpression of the SHC, moreover, the plasmid pLysRAR62 was additionally transformed for the adaptation of the codon usage to E. coli. Furthermore, the plasmid pDHE+ZmSHC-1 from E. coli Lu15568 was used (international application PCT/EP2010/057696). The strains were grown using LB medium at 30° C.

c) Chemicals:

Squalene, (+/−)-citronellal, (+)—R-citronellal and (−)-S-citronellal were purchased from Sigma (Sigma-Aldrich Chemie GmbH, Munich). Restriction enzymes, T4 ligase, and DNA polymerase came from New England Biolabs (New England Biolabs GmbH, Frankfurt).

d) Isolation of DNA and Transformation:

Plasmids were isolated from E. coli using the Qiaprep Spin Miniprep Kits from Qiagen (Qiagen, GmbH, Hilden). For gel extractions or PCR purifications, the Qiaquick Gel Extraction Kit from Qiagen was used. All of the E. coli strains used were transformed using the CaCl₂ method.

e) PCR and Sequencing:

The DNA from Zymomanas mobilis subspec. mobilis CP4 was provided by Prof. Sprenger (Institute of Microbiology. University of Stuttgart). The PCR was carried out using Prime Star Polymerase. The following primers were used for synthesizing the squalene-hopene cyclase gene from Zymomonas mobilis:

SHC_1: SHC-for (SEQ ID NO: 387) TATGCATATGGGTATTGACAGAAT SHC-rev (SEQ ID NO: 388) CCGGATCCTCAATTATTCAAATCAATC

The correctness of the cloned genes was verified by means of sequencing by the company GATC Biotech. Sequence analyses were carried out using the program Clone Manager 7.0. After restriction of the corresponding amplificates, they were cloned in-frame into the pET16b vector using N-terminally encoded His-tag. The plasmids were subsequently transformed first in E. coli DH5α and thereafter in E. coli BL21 (DE3)pLysS and E. coli Rosetta For better expression, the plasmid pLysRAR62 was transformed into the E. coli Rosetta strains in addition to the pET16b constructs. Corresponding clonings with empty vectors were carried out in parallel. In addition, the plasmid pDHE+ZmSHC_(—)1 (corresponding to SHC_(—)1 with codon usage adapted to E. coli) was transformed in E. coli BL21 (DE3)pLysS.

f) Expression and Cell Digestion:

The corresponding E. coli B121 (DE3) pLysS and E. coli Rosetta transformants were cultured in LB medium with ampicillin and chloramphenicol (100 μg/ml and 32 μg/ml, respectively) at 30° C. The synthesis of the squalene-hopene cyclases was induced by addition of 0.5-1 mM IPTG or 0.1% rhamnose (when using the pDHE derivatives) with an OD₆₀₀ of 0.4-0.6. The cells were allowed to grow further for 4-6 hours, and subsequently harvested. This was done by centrifuging off the cells and taking them up in 5 ml/g wet weight of 25 mM Tris/HCl with 40% glycerol. If the cells were not used further immediately, they were stored at −20° C. For digestion of the cells, they were each subjected 2× to a French Press and used, either directly or following removal of the cell debris by centrifugation, for the activity assays. Alternatively, cell digestion took place using ultrasound. Following centrifugation, the SHC proteins were subsequently dissolved with solubilization buffer (50 mM Tris/HCl pH 8, 10 mM MgCl₂, 1% Triton X-100) to remove the cell debris, and hence partially enriched.

g) Activity Assays:

Each batch for determining the activity of the squalene-hopene cyclases had a final volume of 1 ml. This was made up of 600 μl of cells digested by French Press (alternatively 800 μl after solubilization from the cell membrane), 100 mM Na citrate buffer with different pH levels (pH 4.0 to pH 8.0 were used for testing) and 10 mM substrate solution [(+/−)citronellal, (+)-R-citronellal and (−)-S-citronellal]. In addition to the substrate and H₂O, the substrate solution also comprised Triton X-100, which was present in each of the activity batches at a concentration of 0.2%.

The batches were incubated with shaking for 6 hours to 24 hours at temperatures of 22° C., 30° C. and 37° C. The substrate and possible products were extracted with one volume of chloroform hexane/propanol in a ratio of 2:3. The extract was used directly for analysis by gas chromatography.

h) GC Measurements:

The gas-chromatographic measurements took place on an Agilent 7890A gas chromatograph with flame ionization detector. The column used was a DB-5 (Agilent Technologies) with a length of 20 m, a diameter of 0.1 mm and 0.25 μM coating. Substances were identified by comparison of the retention times with available standard solutions.

For verification, the samples were analyzed in parallel on a Shimadzu Gas chromatograph with mass spectrometer. Using the column FS Supreme with a length of 30 m, an internal diameter of 0.25 mm and a coating of 0.25 μm, the retention times were again compared with standard solutions, and the respective mass spectra of the substances present were analyzed.

With the aid of a standard, the diastereomer identified below as isopulegol I was assigned to (1R,3R,6S) or (1S,3S,6R) isopulegol, whereas no assignment was possible for the isomers identified as isopulegol II and isopulegol III.

i) Results of the Activity Assays:

-   Test 1a: (comparative) (controls i.e. results with boiled-off     protein, with empty vector and without protein)

pH pH pH pH 4.0 pH 4.5 5.0 pH 5.5 6.0 pH 6.5 7.0 Citronellal 85.4 85.4 86.0 85.6 84.4 84.7 85.1 Isopulegol I 10.8 10.8 10.4 10.8 11.7 11.5 11.2 Isopulegol II 3.8 3.8 3.6 3.6 3.9 3.8 3.7 Isopulegol III 0 0 0 0 0 0 0

In the information below concerning the substrate rac-citronellal, take place with the amounts of isopulegol found in the controls having already been deducted.

-   2. Test 1b: Comparison of the two overexpressed SHC_(—)1 proteins     (from pDHE and pET16b vector and influence of the His-tag on     activity at pH 4.5)

pDHE pET16b Citronellal 95.2 95.2 Isopulegol I 0.7 0.8 Isopulegol II 1.7 1.6 Isopulegol III 2.4 2.4

-   3. Test 1c: pH dependence

pH pH pH pH 4.0 pH 4.5 5.0 pH 5.5 6.0 pH 6.5 7.0 Citronellal 95.9 94.9 94.7 94.4 95.1 98.7 98.8 Isopulegol I 0.4 0.8 0.8 1.0 1.1 0.8 0.5 Isopulegol II 1.1 2.4 2.1 2.1 1.6 0.5 0.7 Isopulegol III 2.6 1.9 2.4 2.5 2.2 0 0

-   4. Test 1d: Influence of salts at pH 4.5

none BaCl₂ CaCl₂ MgCl₂ Citronellal 94.9 95.2 94.9 95.0 Isopulegol I 0.7 0.8 1.0 0.9 Isopulegol II 2.5 2.4 2.4 2.5 Isopulegol III 1.9 1.6 1.7 1.6

-   5. Test 1e: influence of temperature at pH 4.5

22° C. 30° C. 37° C. Citronellal 95.3 94.9 95.4 Isopulegol I 0.8 1.0 0.8 Isopulegol II 1.8 2.2 1.6 Isopulegol III 2.1 1.9 2.2

-   6. Test 2: S(−)-Citronellal as substrate

pH 4.0 CTRL pH 4.5 CTRL pH 5.0 CTRL pH 5.5 CTRL Citronellal 90.8 95.5 90.8 95.7 91.7 96.2 92.4 96.2 Isopulegol I 4.9 4.5 4.7 4.3 4.4 3.8 4.1 3.8 Isopulegol II 0 0 0 0 0 0 0 0 Isopulegol III 4.3 0 4.5 0 3.9 0 3.5 0 pH 6.0 CTRL pH 6.5 CTRL pH 7.0 CTRL Citronellal 94.1 96.6 96.4 96.5 96.5 96.4 Isopulegol I 3.8 3.4 3.6 3.5 3.5 3.6 Isopulegol II 0 0 0 0 0 0 Isopulegol III 2.1 0 0 0 0 0

-   7. Test 3: R-(+)-Citronellal as substrate

pH 4.0 CTRL pH 4.5 CTRL pH 5.0 CTRL pH 5.5 CTRL Citronellal 80.0 84.2 78.4 83.8 81.1 85.6 81.7 86.8 Isopulegol I 15.9 15.8 16.0 16.2 14.1 14.4 13.5 13.2 Isopulegol II 4.1 0 5.6 0 4.8 0 4.8 0 Isopulegol III 4.3 0 4.5 0 3.9 0 3.5 0 pH 6.0 CTRL pH 6.5 CTRL pH 7.0 CTRL Citronellal 81 85.5 80.8 85.8 81.4 86.2 Isopulegol I 14.3 14.5 14.5 14.2 14.0 13.8 Isopulegol II 4.7 0 4.7 0 4.6 0 Isopulegol III 2.1 0 0 0 0 0

j) Summary of the Results:

The squalene-hopene cyclase from Zymomonas mobilis was prepared recombinantly in E. coli. The enzyme is able to convert citronellal to isopulegol.

Here, the two overproduced Zm-SHC-1 proteins, once without and once with N-terminally appended His-tag, showed no differences in their activity under the conditions tested (cf. Test 1b).

This reaction was verified after 12 hours with the techniques described. The dependence of the reaction on the pH level was low. In a pH range from pH 4 to pH 6, conversion rates totaling about 5% were measured for different isopulegol isomers after 20-hour incubation.

Here it was not critical whether the batches were incubated at RT, 30° C. or 37° C. The conversion was also not increased by addition of divalent ions, such as MgCl₂; for example (cf. Test 1d). What was critical, however, was that the cell extracts, in the case of measurements above a pH of pH 5, either were dialyzed before the substrate was added, or EDTA was added to the batches, in order to suppress reduction of the citronellal substrate to citronellol by enzymes of the host. No effect of this treatment on the activity of the Zm-SHC-1 was found. Where this treatment was not carried out, the substrate was reduced almost completely to citronellol within 20 hours, and there was no longer any measurable cyclization to isopulegol. Zm-SHC-1 is therefore able to cyclize citronellal, but not citronellol, to isopulegol. It is very likely that unspecific dehydrogenases are responsible for the reduction reaction.

In order to rule out a chemical reaction being responsible for the cyclization, boiled-off cell extracts were used. In these controls and in controls with cell extracts from cultivation with empty vectors, however, no corresponding conversion was found (cf. Test 1a).

With (+/−)-citronellal as the substrate it was possible, following the reaction, to detect various isomers of isopulegol, which have not yet been precisely identified (cf. Tests 2 and 3). In order to verify whether these isomers originated from the different isomers of the starting substrate or if only one isomer was accepted as the substrate and was differently converted, the same studies were carried out with (+)-R-citronellal and (−)-S-citranellal. Here it was found that, depending on the substrate, different isopulegol isomers are formed. Interestingly, the conversion of (+)-R-citronellal took place from a pH of 4 to a pH of 7 without substantial differences, at a rate of about 5%. The enantiomer, in contrast, was converted with conversion rates of approximately 4.5% only up to a pH level of pH 6. Here as well, the conversion rate showed virtually no fluctuation in terms of the individual pH levels between pH 4 and pH 6.

Sequences:

SEQ ID NO: 1-326 nucleic acid/amino acid sequences of various SHC genes SEQ ID NO: 327-388 PCR primers

The disclosure of the publications cited herein is expressly referred to.

There follows a listing of SHC enzyme sequences which can be used in accordance with the invention:

Enzyme Sequences >seq_ID 4 MNMASRFSLKKILRSGSDTQGTNVNTLIQSGTSDIVRQKPAPQEPADLSALKAMGNSLTHTLSS ACEWLMKQQKPDGHWVGSVGSNASMEAEWCLALWFLGLEDHPLRPRLGKALLEMQRPDGS WGTYYGAGSGDINATVESYAALRSLGYAEDDPAVSKAAAWIISKGGLKNVRVFTRYWLALIGE WPWEKTPNLPPEIIWFPDNFVFSIYNFAQWARATMMPLAILSARRPSRPLRPQDRLDALFPGG RANFDYELPTKEGRDVIADFFRLADKGLHWLQSSFLKRAPSREAAIKYVLEWIIWHQDADGGW GGIQPPWVYGLMALHGEGYQFHHPVMAKALDALNDPGWRHDKGDASWIQATNSPVWDTML SLMALHDANAEERFTPEMDKALDWLLSRQVRVKGDWSVKLPNTEPGGWAFEYANDRYPDTD DTAVALIAIASCRNRPEWQAKGVEEAIGRGVRWLVAMQSSCGGWGAFDKDNNKSILAKIPFCD FGEALDPPSVDVTAHVLEAFGLLGLPRDLPCIQRGLAYIRKEQDPTGPWFGRWGVNYLYGTGA VLPALAALGEDMTQPYISKACDWLINCQQENGGWGESCASYMEVSSIGHGATTPSQTAWALM GLIAANRPQDYEAIAKGCRYLIDLQEEDGSWNEEEFTGTGFPGYGVGQTIKLDDPAISKRLMQG AELSRAFMLRYDLYRQLFPIIALSRASRLIKLGN >seq_ID 2 MGIDRMNSLSRLLMKKIFGAEKTSYKPASDTIIGTDTLKRPNRRPEPTAKVDKTIFKTMGNSLNN TLVSACDWLIGQQKPDGHWVGAVESNASMEAEWCLALWFLGLEDHPLRPRLGNALLEMQRE DGSWGVYFGAGNGDINATVEAYAALRSLGYSADNPVLKKAAAWIAEKGGLKNIRVFTRYWLALI GEWPWEKTPNLPPEIIWFPDNFVFSIYNFAQWARATMVPIAILSARRPSRPLRPQDRLDELFPE GRARFDYELPKKEGIDLWSQFFRTTDRGLHWVQSNLLKRNSLREAAIRHVLEWIIRHQDADGG WGGIQPPWVYGLMALHGEGYQLYHPVMAKALSALDDPGWRHDRGESSWIQATNSPVWDTM LALMALKDAKAEDRFTPEMDKAADWLLARQVKVKGDWSIKLPDVEPGGWAFEYANDRYPDTD DTAVALIALSSYRDKEEWQKKGVEDAITRGVNWLIAMQSECGGWGAFDKDNNRSILSKIPFCD FGESIDPPSVDVTAHVLEAFGTLGLSRDMPVIQKAIDYVRSEQEAEGAWFGRWGVNYIYGTGA VLPALAAIGEDMTQPYITKACDWLVAHQQEDGGWGESCSSYMEIDSIGKGPTTPSQTAWALM GLIAANRPEDYEAIAKGCHYLIDRQEQDGSWKEEEFTGTGFPGYGVGQTIKLDDPALSKRLLQG AELSRAFMLRYDFYRQFFPIMALSRAERLIDLNN >seq_ID 5 MTVTSSASARATRDPGNYQTALQSTVRAAADWLIANQKPDGHWVGRAESNACMEAQWCLAL WFMGLEDHPLRKRLGQSLLDSQRPDGAWQVYFGAPNGDINATVEAYAALRSLGFRDDEPAVR RAREWIEAKGGLRNIRVFTRYWLALIGEWPWEKTPNIPPEVIWFPLWFPFSIYNFAQWARATLM PIAVLSARRPSRPLPPENRLDALFPHGRKAFDYELPVKAGAGGWDRFFRGADKVLHKLQNLGN RLNLGLFRPAATSRVLEWMIRHQDFDGAWGGIQPPWIYGLMALYAEGYPLNHPVLAKGLDALN DPGWRVDVGDATYIQATNSPVWDTILTLLAFDDAGVLGDYPEAVDKAVDWVLQRQVRVPGDW SMKLPHVKPGGWAFEYANNYYPDTDDTAVALIALAPLRHDPKWKAKGIDEAIQLGVDWLIGMQ SQGGGWGAFDKDNNQKILTKIPFCDYGEALDPPSVDVTAHIIEAFGKLGISRNHPSMVQALDYI RREQEPSGPWFGRWGVNYVYGTGAVLPALAAIGEDMTQPYIGRACDWLVAHQQADGGWGE SCASYMDVSAVGRGTTTASQTAWALMALLAANRPQDKDAIERGCMWLVERQSAGTWDEPEF TGTGFPGYGVGQTIKLNDPALSQRLMQGPELSRAFMLRYGMYRHYFPLMALGRALRPQSHS >seq_ID 78 MTLTSSASARAPRDPGNYQTALQSTVRAAADWLIANQKPDGHWVGRAESNACMEAQWCLAL WFMGLEDHPLRKRLGQSLLDTQRPDGAWQVYFNAPNGDINATVEAYAALRSLGYPDSEPAVR RAREWIEAKGGLRNIRVFTRYWLALIGEWPWEKTPNIPPEVIWFPLWFPFSIYNFAQWARATLM PIALLSARRPSRPLPPENRLDTLFPRGRDAFDYELPVKANAGGWDKFFRGADKVLHALQNFGN RLNLGLFRPAATSRVLEWMIRHQDFDGAWGGIQPPWIYGLMALYAEGYPLNHPVLAKGLDALN DPGWRVDVGEATYIQATNSPVWDTILTLLAFDDAGVLGDYPDAVDKAVNWVLARQVRVPGDW SMKLPHVKPGGWAFEYANNHYPDTDDTAVALIALAPLRHDPKWKAKGIDEAIQLGVDWLIGMQ SQGGGWGAFDKDNNQQILTKIPFCDYGEALDPPSVDVTAHIVEAFGKLGISRNHPSMVQALDYI RKEQEPSGPWFGRWGVNYVYGTGAVLPALAAIGEDMTQPYIGRACDWLVAHQQPDGGWGE SCASYMDISAVGRGTTTASQTAWALMALLAANRPQDKDAIERGCMWLVERQSAGTWDEPEFT GTGFPGYGVGQTIKLTDPSLQERLMQGPELSRAFMLRYGMYRHYFPLMALGRALRPQGHG >seq_ID 209 MDSILAPRADAPRNIDGALRESVQQAADWLVANQKPDGHWVGRAETNATMEAQWCLALWFL GLEDHPLRVRLGRALLDTQRPDGAWHVFYGAPNGDINATVEAYAALRSLGHRDDEEPLRKAR DWILSKGGLANIRVFTRYWLALIGEWPWEKTPNILPEVIWLPTWFPFSIYNFAQWARATLMPIAV LSAHRPSRPLAPQDRLDALFPQGRDSFNYDLPARLGAGVWDVIFRKDTILHRLQDWGARRGP HGIMRRGAIDHVLQWIIRHQDYDGSWGGIQPPWIYGLMALHTEGYAMTHPVMAKALDALNEPG WRIDIGDATFIQATNSPVWDTMLSLLAFDDAGLGERYPEQVERAVRWVLKRQVLVPGDWSVKL PDVKPGGWAFEYANNFYPDTDDTSVALMALAPFRHDPKWQAEGIEDAIQRGIDWLVAMQCKE GGWGAFDKDNDKKILAKIPFCDFGEALDPPSADVTAHIIEAFAKVGLDRNHPSIVRALDYLKREQ EPEGPWFGRWGVNYVYGTGAVLPALAAIGEDMRQPYIARACDWLIARQQANGGWGESCVSY MDAKOAGEGTATASQTAWALMALIAADRPQDRDAIERGCLYLTETQRDGTWQEVHYTGTGFP GYGVGQTIKLNDPLLSKRLMQGPELSRSFMLRYDLYRHYFPMMAIGRVLRQRGDRSGH >seq_ID 193 MNVIRQLNSGVNAAKSLDDGIESAIEWLAENQDKEGFMVGMLESNSCIEAEWILAMHLLGVKD DPKYDKVVQAILNEQREDGSWAVYYDAPAGDINATVEAYAALRTAGFGAGDERLIKARNWIFS HGGLKNVRVFTRYWLALIGEWPWDETPALAPEIIYLPAWCPLNIYDFACWARATLVPLSVLSVR RPVKPLPAESRLDELFPEGRENADYSLPESEKGLAERFFLVVDWFLKKYNRLPMQFGREKAIR LCLEWIVRHQDYDGGWGGIQPPLIYSLIALNTEGYGINHPVISKGLDAFNPPWAYEKNGGVYLQ CSESPVWDTLFTMLALFESGCSFDDTPMMRPALDWILSKQITSWGDWQVKVRGVRPGGWAF ERANTAYPDVDDTALALVVLAEARRHVKDSAAVDAALERAEEWILGLQCRNGGWAAFDRDNN SAIVTKIPFCDFGEVLDPPSVDVTAHVVEALAALGRDRHDPVVARALKYIRSEQEPGGSWFGR WGVNHIYGTCAVLPALAAIGEDMRAPYVLRAADWLVRHQNDDGGWGESCASYMDDSQCGQ GSSTASQTGWALMALVAMSSHDYDEAIRRGLDYLLSHQKSGTWDEPQYTGTGFPGYGVGER TNLKEAGATLDQGCELARGFMINYNMYRHYFPLIAMARARRHLGLAANPRHQDSRSSVEVAPE ALRGRACG >seq_ID 246 MRRLDTFPPEIPTGSRDKPPSGEEHSCSTPAEPLRSRLDEGILRAVDWLVCDQHPDGFWAGM LQSNSCMEAEWVLAMHFLGIDDDPKYDGVIRAILGEQRADGSWGVFHKAPNGDINTTVECYAA LRASGLAPESAPLSSAREWILAGGGLANIRNFTKYWLALIGEWPWEGTPTIPPELIFFPPRMPLN IYHFASWARSTIVPLSILSARRPVRPLPEDRRLDELFPQGRSAFDFRLPRKDGWLSWEGFFHVC DRILRLYARTRRAPFRETAIRVCLEWIIRRQETDGAWSGIQPPWIYALLALHAEGYGLDHPILRA GLRAFDSHWSYERDGGIYLQASESPVWDTVLSLRALADCGEERKASVSIASALEWLLNRQISV PGDWAVRVPSVPCGGWAFQRANSFYPDVDDTAVAIEVLARLRPFTANQSAVDRAIRSARDWV LAMQCSNGGWAAFDRDNDFKLVTKIPFCDFGELLDPPSVDVTAHVIEALAALGWDMTSREIEA AVSFIRREQEAEGSWFGRWGVNHIYGTATVLPALRAIGEDMSSAYVLRAADWLASRQNADGG WGETPASYMDDSLRGVGESTASQTAWAIMGLVAVGSGAHDDTVRRGIDFLLFAQHGGTWEE PQYTGTGFPGYSVGERIRLRDMGASLKQGTELQRAFMINYNLYRHYFPLMALGRARYHLQLRR SAREGGNGETTPNGSAL >seq_ID 151 MKISKNPISHALTSFNDAARETADNSAARKSGKIHHLPATIWKKKESTVSSPLDIAIERTQEFFFR EQLPAGYWWAELESNATITAEYIMLFHFMGLVNREKERKMANYLLRQQTTEGYWTIWHGGPG DLSTTIEAYFALKLAGYPADHPSMSKARAFILEHGGILKARVFTKIFLALFGEFSWLGVPSMPIEM MLLPAGFTFNMYEESSWSRATIIPLSIVMAERPVRKLPPWARVQELYVRPPRPTDYTFTKEDGIL TWKNIFIGIDHVLKVYEASPIRPGRKKAMAIAEKWVLEHQEPTGDWGGIQPAMLNSVLALHVLG YANDHPAVAKGLQALANFCIEGEDELVLQSCVSPVWDTALGLMAMVDSGVPTDHPSLSKAAQ WLLDREVRRPGDWKIKCPDLEPGGWAFEFMNDWYPDVDDSGIVMMAIKNVKVKDQRAKEDTI TRGIAWCLGMQSKNGGWGAFDKDNTKHILNKIPFADLEALIDPPTADLTGRMLELMGTYGYPK DHPAAVRALKFIRETQEPDGPWWGRWGVNYIYGTWSVMSGLAAFGEDMSQPWIRKAVDWLV EHQNEDGGWGECCESYADPRLAGVGPSTASQTGWALLTLLAAGEVASSSVVRGVQYLLDTQ KPDGTWDEDAFTGTGFPKFFMIKYHIYRNCFPLMALGRYRTLAGKGL MKSRKYPISHALTSFNHTTVAPVEAPAPISVKSPAKVHRLPSSIWKKMEGSAGNPLDKAVELTR DFFFREQLPDGYWWAELESNVTITAEYIMLFHFLGMVDKDKERKMANYLLRQQTEEGYWTVW HNGPGDLSTTIEAYFALKLAGYHADHIALRKARDFILANGGILKSRVFTKTFLAMFGEFSWLGVP SMPIELMLLPDWAYLNVYEFSSWARATIIPMSVLMANRPVYKLPPHARVQELYVRPPRPTDYTF TKEDGIFSLKNFFIGVDHLLKIYESSPIRPFKKRATEKVEQWILEHQEKTGDWGGIQPAMLNAILA LHCLGYANDHPAVAKGLEALANFTIEDSDSLVLQSCISPVWDTALVLQAMQEASVPLDHPSLIK ASQWLLDREVRIKGDWKIKSPDLEPGGWAFEFQNDWYPDVDDSTAVMIAIKDIKVKNTKARQD AIRRGIDWCLGMQSENGGWAAFDKDNTKHMLNKIPFADLEALIDPPTADLTGRMLELMGNFGY TKDHPQAVSALEFLKNEQEPEGPWFGRWGVNYIYGTWYVLIGLEAIGEDMNSPYIKKSVNWIK SRQNLDGGWGEVCDSYWDRTLMGCGPSTASQTSWALMALMAAGEVGCQAVERGIQYLLAT QNSDGTWDEEAFTGTGFPKYFMIKYHIYRNCFPLTALGRYRRLTAGTHAQ >seq_ID 152 MNSCKHPISHALTSFNGETADAAKKQPVKPGAKIHHLPASIWKKKEGESKSPLDIAIENSRDFFF REQLPDGYWWAELESNCTITAEYLMLYHFMGIVDQERERKMATYLLSKQTAEGFWTIYFGGPG DLSTTVEAYFALKLAGYPADHPAMAKARAFILDNGGIIKCRVFTKIFLALFGEFAWFGVPSMPIEL ILLPNWAYFNMYELSSWSRATIIPLSIVMTERPVRKLPPSSRVQELYVRPPRPIDYTFSKEDGIIT WKNFFIGVDHILKVYESNPIRPFKKRALATAENWVLDHQESTGDWGGIQPAMLNSVLALHCLG YANDHPAVAKGLEALANFCIETEDSLVLQSCISPIWDTALALKALVDSDVPTDHPALVKAAQWLL DKEVRKPGDWKIKCPELESGGWAFEFLNDWYPDVDDSGFVMMALKDVAVKDRKSMDGAIKR GINWCLGMQSKNGGWGAFDKDNTKYLLNKIPFADLEALIDPPTADLTGRMLELMGTFGYSKDY PAAVRALEFIKKNQEPEGSWWGRWGVNYIYGTWSVLGGLAAIGEDLNQPYIRKAVNWLKSRQ NMDGGWGETCESYHDTSLAGIGESTPSQTGWALLSLMSAGEANSSTVARGIQYLIANQKSDG TWDEEQYTGTGFPKFFMIKYHIYRNCFPLTALGTYRKLTGGMA >seq_ID 146 MTSPFKHPISNALTSFNGNFAEPEQCVEQQTGAKVHHLPASIWKRKMGKAKSPLDVAIEGSRD FFFQEQLPKGYWWAELESNVTITAEYIMLFHFLGLVDRERQRKMSNYLLSKQTEEGFWPIYYG GPGDLSTTIEAYFALKLSGYPADHPALAKARAFILEQGGVVKSRVFTKIFLALFGEFEWQGVPS MPVELNLLPDWAYINIYEFSSWARATIVPLSVVMHSRPVRRVPPSARVQELFVRQPTAADYSFA KNDGIFTWENFFLGLDRVLKVYEKSPLRPFKNMALAKAEEWVLEHQEPTGDWGGIQPAMLNA VLALNVLGYQNDHPAVEQGLRALANFCIETEDQLVLQSCVSPVWDTALALKALLDAGVPPDHP SLVKGAQWLLDKEVTRPGDWRVKSPALEPGGWAFEFLNDWYPDVDDSGFVMIALKGIQVKDR KSMDAAIKRGINWCLGMQSKNGGWGAFDKDNTRHVLNKIPFADLEALIDPPTADLTGRMLELM GTFNYPITLPAAQRAIEFLKKNQEPEGPWWGRWGVNYLYGTWSVLCGLAAIGEDMDQPYIRKA VNWIKSRQNIDGGWGETCQSYHDRTLAGVGESTPSQTGWALLGLLAAGEMHSATVVRGVQY LISTQNSDGTWDEQQYTGIGFPKYFMIKYHIYRNCFPLMALGTYRTLTRTQP >seq_ID 147 MSPCKHPISHALTSFNGETADSVPVQTPKTGAKIHHLPPSIWKKKEGELKSPLDIAIENSRDFFF REQLPDGYWWAELESNCTITAEYVMLYHFMDLVDRERERKMANYLLSKQTEEGFWTIYYGGP GDLSTTVEAYFALKLAGYPADHPAMVKARAFILDNGGIIKTRVFTKIFLALFGEFAWFGVPSMPIE LILLPNWAYFNMYELSSWSRATIIPLSIVMTQRPVRKLPPASRVQELYVRPPSPIDYTFTKEDGIF TWKNFFIGVDHILKVYESNPIRPFKKKAMLAAENWVLEHQEATGDWGGIQPAMLNSVLALHCL GYANNHPAVAKGLEALENFCIESEDSLVLQSCISPVWDTALALKALVDSDVPNDHPALVKAAQ WLLDKEIRKAGDWKVKSPELEPGGWAFEFLNDWYPDVDDSGFVMMALKDVAVKDRKSMDTAI KRGISWCLGMQSKNGGWGAFDKDNTKYLLNKIPFADLEALIDPPTVDLTGRMMELMGTFGYAK DYPPAVRALDFIKRNQEPDGSWWGRWGVNYIYGTWSVLCGLSAMGEDLNQPYIRKAINWLKS RQNIDGGWGETCESYHDSSLAGIGASTASQTGWALLALMAVGEENASAVARGVQYLLATQKS DGTWDEDLYTGTGFPKFFMIKYHIYRNCFPLTALGTYRRKTGGRAEMQVSEHNK >seq_ID 144 MKISKHPISHALTSFNETAKETKEEPQKKRGGKVHHLPASIWKKRDVETTSPLDQAIKRSQEFFL REQLPAGYWWAELESNVTITAEYVILFHFMGLVNRDKDRKMATYLLSKQTEEGCWCIWHGGP GDLSTTIEAYFALKLAGYPADHPAMQKARTFILGKGGILKARVFTKIFLALFGEFSWLGVPSMPIE MMLLPNGFTFNLYEFSSWSRATIIPLSIVMAERPVRKLPPWARVQELYVRPPRPMDYTFTKEDG ILTWKNIFIGIDHILKVYEASPIRPGMKKAMAIAEQWVLDHQEPTGDWGGIQPAMLNSVLALHCL GYANDHPAVAKGLQALANFCIESDDEIVLQSCISPVWDTALALMAMVDSEVPTDHPALVKAAQ WLLDREVRKVGDWKIKAPNLEPGGWAFEFQNDWYPDVDDSGIVMMAIKDVKVKDSKAKAEAI QRGIAWCIGMQSKNGGWGAFDKDNTKHILNKIPFADLEALIDPPTADLTGRMLELMGTFGYPK DHPAAVRALQFVKENQEPDGPWWGRWGVNYIYGTWSVLCGLKAYGEDMGQPYVRKAVEWL AAHQNPDGGWGECCESYCDQKLAGTGPSTASQTGWALLSMLAAGDVDHPAVARGIRYLIETQ QPDGTWDEDQFTGTGFPKYFMIKYHIYRNCFPLMAMGRYRALKGHKG >seq_ID 15 MAEQLVEAPAYARTLDRAVEYLLSCQKDEGYWWGPLLSNVTMEAEYVLLCHILDRVDRDRME KIRRYLLHEQREDGTWALYPGGPPDLDTTIEAYVALKYIGMSRDEEPMQKALRFIQSQGGIESS RVFTRMWLALVGEYPWEKVPMVPPEIMFLGKRMPLNIYEFGSWARATVVAISIVMSRQPVFPL PERARVPELYDTDVPPRRRGAKGGGGRIFDALDRALHGYQKLSVHPFRRAAEIRALDWLLERQ AGDGSWGGIQPPWFYTLIALKILDMTQHPAFIKGWEGLELYGVDLDYGGWMFQASISPVWDT GLAVLALRAAGLPADHDRLVKAGEWLLDRQITVPGDWAVKRPNLKPGGFAFQFDNVYYPDVD DTAVVVWALNSLRLPDERRRRDVMTKGFRWIVGMQSSNGGMGAYDVDNTSDLPNHIPFCDF GEVTDPPSEDVTAHVLECFGSFGYDDAWKVIRRAVEYLKREQRPDGSWFGRWGVNYLYGTG AVVPALKAVGIDVREPFIQKALDWVEQHQNPDGGWGEDCRSYEDPAYAGKGASTPSQTAWA LMALIAGGRAESDSVRRGVQYLVETQRPDGGWDEPYYTGTGFPGDFYLGYTMYRHVFPTLAL GRYKQAIERR >seq_ID 16 MAEQLVEAPAYARTLDRAVEYLLSCQKDEGYWWGPLLSNVTMEAEYVLLCHILDRVDRDRME KIRRYLLHEQREDGTWALYPGGPPDLDTTIEAYVALKYIGMSRDEEPMQKALRFIQSQGGIESS RVFTRMWLALVGEYPWEKVPMVPPEIMFLGKRMPLNIYEFGSWARATVVALSIVMSRQPVFPL PERARVPELYETDVPPRRRGAKGGGGWIFDALDRALHGYQKLSVHPFRRAAEIRALDWLLER QAGDGSWGGIQPPWFYALIALKILDMTQHPAFIKGWEGLELYGVELDYGGWMFQASISPVWD TGLAVLALRAAGLPADHDRLVKAGEWLLDRQITVPGDWAVKRPNLKPGGFAFQFDNVYYPDV DDTAVVVWALNTLRLPDERRRRDAMTKGFRWIVGMQSSNGGWGAYDVDNTSDLPNHIPFCD FGEVTDPPSEDVTAHVLECFGSFGYDDAWKVIRRAVEYLKREQKPDGSWFGRWGVNYLYGT GAVVSALKAVGIDTREPYIQKALDWVEQHQNPDGGWGEDCRSYEDPAYAGKGASTPSQTAW ALMALIAGGRAESEAARRGVQYLVETQRPDGGWDEPYYTGTGFPGDFYLGYTMYRHVFPTLA LGRYKQAIERR >seq_ID 141 MTSPFKHPISNALTSFNGNVAEPEQSVEQQSGAKVHHLPASIWKRKMGRAKSPLDVAIEGSRD FFFQEQLPKGYWWAELESNVTITAEYIMLFHFLGLVDPERQRKMSTYLLSKQTEEGFWTIYYG GPGDLSTTIEAYFALKLSGYPEDHPALAKARAFILEQGGVVKSRVFTKIFLALFGEFDWQGIPSM PVELNLLPDWAYINIYEFSSWARATIVPLSVVMHSRPVRRVPPSARVQELFVRQPTAADYSFAK NDGLFTWEKFFLGLDRVLKVYEKSPLRPFKKTALAKAEEWVLEHQEPTGDWGGIQPAMLNAIL ALNVLGYRNDHPAVEQGLRALANFCIETEDQLVLQSCVSPVWDTALALKALLDAGVPPDHPSL VKGAQWLLDKEVTRAGDWRVKSPNLEAGGWAFEFLNDWYPDVDDSGFVMIALKGIQVKDHK AMDAAIKRGINWCLGMQSKNGGWGAFDKDNTKHVLNKIPFADLEALIDPPTADLTGRMLELMG TFDYPVTFPAAQRAIEFLKKNQEPEGPWWGRWGVNYLYGTWSVLCGLAAIGEDMDQPYIRKA VNWIKSRQNIDGGWGETCQSYHDRTLAGVGESTPSQTGWALLSLLAAGEMHSATVVRGVQYL ISTQNSDGTWDEQQYTGTGFPKYFMIKYHIYRNCFPLMALGTYRTLTRTQP >seq_ID 195 MNPAKYKISSSLTSLNAEPVEQAPLPAKRTGSKVHRLPPSIWKKMVAEAKSPLDKGIERTRDFF LREQLPDGYWWAELESNVTISAEYVMLFHFLGMVDRERERKLANYILAKQTSEGFWSLWHNG PGDLSTTIEAYFALKLAGYSADHPAMAKARAFVLANGGIIKARVFTKIFLALFGEFAWFGVPSMPI ELMLLPDWAYFNMYEFSSWSRATIIPLSVVMSERPVRKLPPRAQVQELFVRPPRPTDYTITRED GLFTWKNFFIGADHLIKVYESSPIRPFKKRAVALAENWILEHQEQSGDWGGIQPAMLNSILALHC LGYANDHPAVAKGLDALANFCIEDDDCIVLQSCVSPVWDTALALVALQEADVPADHPALVKAA QWLLNLEVRRKGDWQVKCPELEPGGWAFEFLNDWYPDVDDSGFVMLSIKNIKVRDRKHREE AIKRGIAWCLGMQSENGGWGAFDRNNTKYLLNKIPFADLEALIDPPTADLTGRMLELMGNFDY PKSHPAAERALAFLKKEQESEGPWWGRWGVNYLYGTWSVLCGLEAIGEDMNQPYIRKAVNWI KSRQNNDGGWGEVCESYFDRSLMGSGPSTASQTGWALLALMAAGEANSRAAAQGVKYLLET QNEDGTWDEDAFTGTGFPKFFMIKYHIYRNCFPLTALGRYRRLTAAKG >seq_ID 3 MTATTDGSTGASLRPLAASASDTDITIPAAAAGVPEAAARATRRATDFLLAKQDAEGWWKGDL ETNVTMDAEDLLLRQFLGIQDEETTRAAALFIRGEQREDGTWATFYGGPGELSTTIEAYVALRL AGDSPEAPHMARAAEWIRSRGGIASARVFTRIWLALFGWWKWDDLPELPPELIYFPTWVPLNI YDFGCWARQTIVPLTIVSAKRPVRPAPFPLDELHTDPARPNPPRPLAPVASWDGAFQRIDKALH AYRKVAPRRLRRAAMNSAARWIIERQENDGCWGGIQPPAVYSVIALYLLGYDLEHPVMRAGLE SLDRFAVWREDGARMIEACQSPVWDTCLATIALADAGVPEDHPQLVKASDWMLGEQIVRPGD WSVKRPGLPPGGWAFEFHNDNYPDIDDTAEVVLALRRVRHHDPERVEKAIGRGVRWNLGMQ SKNGAWGAFDVDNTSAFPNRLPFCDFGEVIDPPSADVTAHVVEMLAVEGLAHDPRTRRGIQW LLDAQETDGSWFGRWGVNYVYGTGSVIPALTAAGLPTSHPAIRRAVRWLESVQNEDGGWGE DLRSYRYVREWSGRGASTASQTGWALMALLAAGERDSKAVERGVAWLAATQREDGSWDEP YFTGTGFPWDFSINYNLYRQVFPLTALGRYVHGEPFAKKPRAADAPAEAAPAEVKGS >seq_ID 18 MTKQLLDTPMVQATLEAGVAHLLRRQAPDGYWWAPLLSNVCMEAEYVLLCHCLGKKNPEREA QIRKYIISQRREDGTWSIYPGGPSDLNATVEAYVALKYLGEPASDPQMVQAKEFIQNEGGIEST RVFTRLWLAMVGQYPWDKLPVIPPEIMHLPKSVPLNIYDFASWARATIVTLSYRHESPTCDATS GLCKGSGIVRGEGPPKRRSAKGGDSGFFVALDKFLKAYNKWPIQPGRKSGEQKALEWILAHQ EADGCWGGIQPPWFYALLALKCLNMTDHPAFVKGFEGLEAYGVHTSDGGWMFQASISPIWDT GLTVLALRSAGLPPDHPALIKAGEWLVSKQILKDGDWKVRRRKAKPGGWAFEFHCENYPDVD DTAMVVLALNGIQLPDEGKRRDALTRGFRWLREMQSSNGGWGAYDVDNTRQLTKSDSIFATS GEVIDPPSEDVTAHVLECFGSFGYDEAWKVIRKAVEYLKAQQRPDGSWFGRWGVNYVYGIGA VVPGLKAVGVDMREPWVQKSLDWLVEHQNEDGGWGEDCRSYDDPRLAGQGVSTPSQTAW ALMALIAGGRVESDAVLRGVTYLHDTQRADGGWDEEVYTGTGFPGDFYLAYTMYRDILPVWA LGRYQEAMQRIRG >seq_ID 245 MNPIRGKRGSAADFLEEEYQWENLADHGESGRTPGGGHPAALKEYEAGSATEHTGHHCVHH LGVRNSWLRKIEKAIDNACGQLFKTQYEDGYWWSELESNVTITSEYIMLLYLLEVSRPEQQKSM VKYLLNQQRPDGSWGLYYGDGGNLSTTIEAYFALKLAGEHCESEPMRRAREFILSKGGIESAR VFTKIWLALFSQYDWDKVPSMPVELVLLPSSLYFNIYEFSSWARGTVVPLSIVMSIRPRCPLPAK CSIKELYVPGSKHKNFASCTHKLFFLFDRIAKAFERRPVPSLRNKAVQAAETWVLDHQEDSGD WGGIQPPMVYSVLALYYLGYPLDHEVIVKGIKALDAFCMEDEEGTRMQSCVSPVWDTALTVLS MLDAGVAAEHPGLEKAGRWLLENQVLTGGDWQIKNDSLPGGWAFEFYNTRYPDVDDSAVVL STLNRFNAERVEGLEFAKCRGMEWCLSMQSSNGGWAAFDKDNTLEILNRIPFADQEAMVDYP TADVTGRVLEAMGYLGYDGSHPRARKAIQFLKKRQERDGCWWGRWGVNYIYGTWSVLKGLI SIGEDPRAAYIRAAVRWVKDHQNSDGGWGETCESYENPELRGQGPSTPSQTAWALMSLIACG EMKSQEASRGIQYLLRTQKRDGTWEELHFTGTGFPKHFYIRYHNYRNCFPLMALGQYLRALER >seq_ID 221 MTATTDGSTGALPPRAASASEPHDTIPQAAGSVGIQDAAARATQRATDFLLSRQDAEGWWKG DLETNVTMDAEDLLLRQFLGIQDEKTTRAAGLFIRGEQRADGTWATFYGGPGDLSATIEAYVAL RLAGDGPDEPHMAKASAWIRERGGIASARVFTRIWLALFGWWKWDDLPELPPELIYFPKWMP LNIYDFGCWARQTIVPLTVVSAKRPVRPAPFPLDELHADANDPNPAKPLAPMVSWDGLFQRLD VALHTYRKVAPRRLRKAAMNTAARWIIERQENDGCWGGIQPPAVYSVIALYLLGYDLEHPVMR EGLASLDRFAVWRDDGARMIEACQSPVWDTCLATIALADAGVPADHPQLVRAADWMLGEEIV RPGDWAVKRPQLPPGGWAFEFHNDNYPDIDDTAEVVLALRRVKHHDPERLDNAIRRGVRWNL GMQSKDGGWGAFDVDNTSPFPNRLPFCDFGEVIDPPSADVTAHVVEMLAFEGLSHDPRTRR GIQWLLSAQEANGSWFGRWGVNYVYGTGSVVPALVAAGLPASHPAIRRAVTWLETVQNDDG GWGEDLRSYPEAAEWSGKGASTASQTGWALLALLAAGERESKAVERGIEWLAQTQRPDGSW DEPYFTGTGFPWDFSINYHLYRQVFPLTALGRYVNGEPLVEVKGG >seq_ID 160 MKGKEPTREELLSFSSGIQMDSSAENTTPVSTEELQEKVRLAAESLISRQVEEGYWVEPLEAD VTITSEYILLQYLLGRERDEFFRRAAPFILESQGEDGGWPLYHGGPAEISATVKAYLALKLLGYD ADHPAMQRARALVLERGGAINVNVFTRITLALFGQYDWKGVPALPPEMILLPRWFPLSIYTVSY WSRTVIVPLLFIYHYKPLLELPPEKGVQELFITPMSEVRVHYAWDKHWVSWKNLFFVLDRILQA WNRHPPSFLRRKALKKAMEWMIPRLKGEGGLGAIYPAMANSVLALRLEGYAMDHPLVRRAIQS IDDLVFDLGEQQSVQPCHSPIWDTALALGALYEAGLDEGSPFVSRALDWFCRKEVRTVGDWS VRVPGVEAGGWAFQFENDYYPDIDDTSVVLMDFAKWVPEMGAYRDVFRRAIEWTLSMQGTD GGWGAFDKDNDFLFLNNIPFADHGALLDPSTSDVTGRVTELLGILGYDARTPVVRRALRFLRKE QEENGSWYGRWGVNYIYGTWSVVSALKAVGEDMSAPYVQKAMQFLFSRQNPDGGWGESCY SYFRKDTAGEGVSTSSQTAWALIALIHGGHVRHPAVSKGIDFLLSRQQADGKWLEQEYTGTGF PKVFYLRYNMYRDYFSLWALSLYRNVLLDGQSRVERLARRWKGNPYPVRSRFLA >seq_ID 161 MEGKDPTREELLSFTSGIQMDSRVGNTNPVSTEELQEKVRLAAESLISRQGEEGYWVEPLEAD ITITSEYVLLQYLLGRERDEFFRRAAPFILESQGEDGGWPLYNGGPAEISATVKAYLALKLLGYD ADHPAMQRARALVLERGGAINVNVFTRITLALFGQYDWKGVPALPPEMILLPRWFPLSIYTVSY WSRTVIVPLLFIYHYKPLLELPPEKGVQELFITPMSEVRVHYAWDKHWVSWKNLFFVLDRILQA WNRHPPSFLRRKALKKAMEWMIPRLKGEGGLGAIYPAMANSVLALRLEGYEMDHPLVRRAIQS IDDLVFDLGEQQSVQPCHSPIWDTALALGALYEAGLDEGSPFVSRALDWFCRKEVRTVGDWS VRVPGVEAGGWAFQFENDYYPDIDDTSVVLMDFAKWVPEMGAYRDVFRRAIEWTLSMQGTD GGWGAFDKDNDFLFLNNIPFADHGALLDPSTSDVTGRVTELLGILGYDARTPVVRRALRFLRKE QEENGSWYGRWGVNYIYGTWSVVSALKAVGEDMSAPYVQRAMQFLFSRQNPDGGWGESCY SYFRKDTAGEGVSTASQTAWALIALIHGGHVRHPAVSKGIDFLLSRQQADGKWLEQEYTGTGF PKVFYLRYNMYRDYFSLWALSLYRNVLLDGQSRVERLSRRWKGTPYPVRSRFLA >seq_ID 240 MHEGEAMTATTDGSTGALPPRAAAASETHLDTPVAAGIQEAAVRAVQRATEHLLARQDAEGW WKGDLETNVTMDAEDLLLRQFLGIRDESTTRAAAKFIRGEQREDGTWAGFYGGPGELSTTVEA YVALRLDGDAPDAPHMAKASAWIRAQGGIAAARVFTRIWLALFGWWKWEDLPELPPELIYFPK WAPLNIYDEGCWARQTIVPLTIVSAKRPVRPAPFPLDELHADPADPNPAKPLAPVASWDGAFQ RLDKAMHQLRKVAPRRLRRAAMNSAARWIIERQENDGCWGGIQPPAVYSVIALHLLGYDLQHP VMRAGLESLDRFAIWREDGSRMIEACQSPVWDTCLATIALVDAGVPADHPQLVKAADWMLGE EIVRPGDWSVKRPQLPPGGWAFEFHNDNYPDIDDTAEVVLALRRVRHHDPDRVENAIGRGVR WNLGMQSKNGAWGAFDVDNTSPFPNRLPFCDFGEVIDPPSADVTAHVVEMLAVEGLSHDPRT RRGIEWLLAEQEPDGSWFGRWGVNYIYGTGSVVPALTAAGLPASHPAIRRAVAWLEKVQNDD GGWGEDLRSYKYVKEWSGRGASTASQTAWALMALLAAGERDSKAVERGVEWLASTQRADG SWDEPYFTGTGFPWDFSINYHLYRQVFPLTALGRYVHGEPFSRTEAL >seq_ID 231 MTATTDGSSGPVRAGAATAGDTTTTTAARTTAPGTDVREAAGRAAERAVEHLLARQDAQGW WKGDLETNVTMDAEDLLLRQFLGIQDAATVEASARFIRGQQRDDGTWATFYGGPGELSTTIEA YVALRLAGDRPDDPHMQRAASWVRSRGGIAAARVFTRIWLALFGWWKWDDLPELPPELILLPK WVPLNIYDFGCWARQTIVPLTVVSAKRPVRPAPFALDELHTDPAMPNPQKRFAPAASWDGFF QRADKALHLYHKVAPRRLRRAAMNAAARWIIERQENDGCWGGIQPPAVYSVIALHLLGYDLEH PVMRAGLESLDRFAVHREEEGLPVRMIEACQSPVWDTCLATIALADAGLPADHPALVKAADWM LSEQIVRPGDWAVRRPGLGPGGWAFEFHNDNYPDIDDTAEVILALRRVKHPDPERVEAAVARG TRWNLGMQSLNGAWGAFDADNTSPFPNRLPFCDFGEVIDPPSADVTAHVVEMLAHEGMAED PRTRRGVRWLLREQEANGAWFGRWGVNYVYGTGAVVPALIAAGLPASHPSVRRAVTWLESV QNEDGGWGEDLRSYREEQSIGRGASTASQTGWALLALLSAGERDGRAVERGVAWLARTQRP DGSWDEPYFTGTGFPWDFSINYHLYRQVFPLTALGRFLHGEKPVGRAAAREGG >seq_ID 227 MTATTDGSTGAANPSEATAHDPTDTTTAADDLTVAARRAAERSVEHLLGRQDEQGWWKGDL ATNVTMDAEDLLLRQFLSIQDPETTRAAALFIRGEQLGDGTWNTFYGGPGDLSATIEAYVALRL AGDRPDEPHMARAAGWIRDQGGIAAARVFTRIWLALFGWWKWDDLPELPPELMFFPKWVPL NIYDFGCWARQTIVPLTIVSAKRPVRPAPFALDELHTDPDHPNPPRKLAPPTSWDGLFQRLDKG LHLYHKVAPRPLRRVAMNLAARWIIERQENDGCWGGIQPPAVYSVIALHLLGYDLDHPVMKAG LASLDRFAVRREDGARMIEACQSPVWDTCLATIALADAGLRPDHPALVKAADWMLAEEITRPG DWSVRKPELAPGGWAFEFHNDNYPDIDDTAEVVLALRRVRHPDPARLQAAIDRGVRWNLGM QSRNGAWGAFDADNTSPFPNRLPFCDFGEVIDPPSADVTGHVVEMLAVEGLASHPRTREGIE WLLAEQEACGAWFGRWGVNYVYGTGSVVPALITAGLPAGHPAIRRAVAWLESVQNDDGGWG EDLRSYQEEKWIGHGESTASQTAWALLALLAAGRRDTRPVARGVTWLTEAQQADGSWDEPY FTGTGFPWDFSINYHLYRQVFPLTALGRYVHGDPFADRAMAAEGA >seq_ID 121 MQTQNRVTSTQKVELSNLTKAIIASQNYIMSRQYPEGYWWGELESNITLTAETILLHKIWKTDKT RPFHKVETYLRRQQNEQGGWELFYGDGGELSTSVEAYMALRLLGVTPEDPALIRAKDFILSQG GISKTRIFTKFHLALIGCYDWKGIPSIPPWIMLFPDNFPFTIYEMSSWARESTVPLLIVFDKKPIFEI EPAFNLDELYAEGVENVKYALPRNHNWSDIFLGLDKLFKWTEKNNLVPFHKKSLQAAERWMLN HQQESGDWGGIMPPMVNSLIAFKVLNYDVADPSVQRGFEAIDRFSIEEEDTYRVQACVSPVWD TAWVIRALVDSGLKPDHPSLVKAGEWLLDKQILEYGDWAIKNKQGKPGGWAFEFINRFYPDLD DSAVVVMALNGIKLPDENCKKAAINRCLEWMATMQCKPGGWAAFDVDNDQAWINEIPYGDLK AMIDPNTADVTARVLEMVGSCGLKMDENRVQKALFYLEKEQESDGSWFGRWGVNYIYGTSGV LSALAVIAPNTHKPQMEKAVNWLISCQNEDGGWGETCWSYNDPSLKGTGVSTASQTAWALIG LLDAGEALETLATDAIKRGINYLLDTQTPDGTWEEAEFTGTGFPCHFYIRYHLYRHYFPLIALGR YWKIGLKNLKG >seq_ID 120 MQTQNRVTSTQKVELSNLTQAIIASQNYILSRQYPEGYWWGELESNITLTAETVLLHKIWKTDKT RPFHKVETYLRRQQNEQGGWELFYGDGGELSTSVEAYMALRLLGVTPEDPALIRAKDFILSKG GISKTRFTKFHLALIGCYDWKGIPSIPPWIMLFPDNFPFTIYEMSSWARESTVPLLIVFDKKPIFEI EPAFNLDELYAEGVENVKYALPRNHNWSDIFLGLDKLFKWTEKNNLVPFHKKSLQAAEKWMLN HQQESGDWGGIMPPMVNSLIAFKVLNYDVADPSVQRGFEAIDRFSIEEEDTYRVQACVSPVWD TAWVIRALVDSGLKPDHPSLVKAGEWLLDKQILEYGDWAIKNKQGKPGGWAFEFINRFYPDLD DSAVVVMALNGIKLPDENRKKAAINRCLEWMATMQCKPGGWAAFDVDNDQAWINEIPYGDLK AMIDPNTADVTARVLEMVGSCGLKMDENRVQKALFYLEKEQESDGSWFGRWGVNYIYGTSGV LSALAVIAPNTHKPQMEKAVNWLISCQNEDGGWGETCWSYNDSSLKGTGISTASQTAWAIIGL LDAGEALETLATDAIKRGIDYLLATQTPDGTWEEAEFTGTGFPCHFYIRYHLYRHYFPLIALGRY WKIGLKTPSVIPLN >seq_ID 132 MFQGSDRPPVTLVMNDMRGPDMNVSDTVSVTRESIPTQTSAGDATARDLTAAVGSELTRALR LATDHLLALQDGTGWWKFDLETNTSMDAEDLLLREYLGIRTTEVTAASARFIRSRQSDDGSWP QYFGGPGELSTTVESYIALRLAGDDASAPHMLSAATWVRDHGGVPATRVFTRIWLALFGWWR WEDLPALPPEIMLLPRRAPLNIYSFGSWARQTLVSLTVVSALRPVRPAPFDLDELYPDGPASAW SGAGPSNVLERISTRFTAKEIFLGIDRLLHVYHRRPVRSMRNHALRAAERWIIARQEADGCFGGI QPPAVYSIIALRLLGYELDHPVLKAALRALDDYSVTLPDGSRMVEASQSPVWDTALAVNALADA GATAAIAPDHPALVRAAGWLLGQEVRHRRGDWAVNHPDVPASGWAFEFENDTYPDTDDTAE VLLALRRVRHPARDELDAAERRAVAWLFGLQSSDGGWGAYDADNTSTIPYQIPFADFGALTDP PSADVTAHVVELLAEAGLGGDDRTRRGVDWLLDHQEADGSWFGRWGVNYVYGTGSVMPAL RAAGLEPSHPAMRAGADWLLTHQNADGGWGEDLRSYTDPEWSGRGESTASQTAWAMLALL TVGDQPEVSGALARGARWLADHQRPDGSWDEDQFTGTGFPGDFYINYHGYRLLWPIMALGR YLRG >seq_ID 118 MLTYKEYRRSVTEIAMQTRDRQTQKPALSLNDAITASQNYLLSLQYPQGYWWAELESNITLTAE TVLLHKIWGTDKTRPLHKVEAYLRQQQREQGGWELFYGDGGEISTSVEAYMALRLLGVPQDD PALIRAKDFILSKGGISKTRIFTKFHLALIGCYSWKGIPSIPPWIMLFPNSFPFTIYEMASWAREST VPLIIVFNDKPVFAVDPIFNLDELYAEGIENVKYELPKNNNWGDIFLGLDKVFKFAEQVDLVPFRK KGLQAAERWMLNHQQETGDWGGIMPPMVNSLLAFRVLNYDVNDPSVQRGFEAIDRFSIEENE TYRVQACVSPVWDTAWCVRALTNSGLPKDHFSLVKAGKWLLEKQCLEYGDWAVKNKTGKPG GWAFEFTNRFYPDIDDSAVVVMALNGIKLPDEARKQAAINRCVKWIETMQCKEGGWAAFDVD NDQAWLNEVPYGDLKAMIDPNTADVTARVVEMVGSCDLEISSKRLNKALNYLYKEQEKDGSW FGRWGVNYIYGTSGVLSALAVINPEKHQPQIEQGINWLLSCQNKDGGWGETCWSYNDSNLKG KGISTASQTAWALIGLLDAGEALNHFETDSIQRGISYLLNTQTEEGTWEESEFTGTGFPCHFYIR YHFYRHYFPLIALGRYQNLSSEFGIRNSEL >seq_ID 230 MTATTDGSSGPLRGGAATAGETTSTSAARTTEPGTDLREAAARAAERAVEHLLARQDAEGWW KGDLETNVTMDAEDLLLRQFLGIQDPATVGASARFIRGQQRDDGTWATFYGGPGELSTTVEAY VALRLAGDRPDDPHMQRAASWVRSRGGIAASRVFTRIWLALFGWWKWEDLPELPPELIFLPK WFPLNIYDFGCWARQTIVPLTVVSAKRPVRPAPFALDELHTDPALPNPGKRLAPAASWDGFFQ RADKALHAYHKVAPRRLRRAAMNAAARWIIERQENDGCWGGIQPPAVYSVIALHLLGYDLEHP VMRAGLESLDRFAVHHEEEGLPVRMIEACQSPVWDTCLATIALADAGLPADHPALVKAADWML SEQIVRPGDWSVRRPGLGPGGWAFEFHNDNYPDIDDTAEVVLALRRVKHPDPERVDAAVARG TRWNLGMQSRDGAWGAFDADNTSPFPNRLPFCDFGEVIDPPSADVTAHVVEILAHEGMAHDP RTRRGVRWLLAHQEANGAWFGRWGVNYVYGTGAVVPALTAAGLPGSHPAIRRAVAWLESVQ NEDGGWGEDLRSYREEKSIGRGVSTASQTGWALLALLAAGERESKAVERGVAHLAQTQAPD GSWDEPYFTGTGFPWDFSINYHLYRQVFPLTALGRYVHGEKLPGRAGAREGR >seq_ID 234 MHEGEAMTATTDGSTGAATPPATTASAPLHLSPEARETHEATARATRRAVDFLLARQSDEGW WKGDLATNVTMDAEDLLLRQFLGIRDEATTRAAALFIRGEQQEDGTWNTFYGGPGDLSATIEG YVALRLAGDSPEAPHMRKASAFVRAQGGVARARVFTRIWLALFGWWKWEDLPEMPPELMFF PKWAPLNIYDFGCWARQTIVPLTVVCAQRPVRPAPFALEELHTDPADPDPAQPAPPVVSWDNV FHKLDKLLHGYRRIAPRRVREAAMRAAATWIVERQENDGCWGGIQPPAVYSIMALNLLGYDLD HPVLRAGLASLDRFAVWREDGARMIEACQSPVWDTCLATVALADAGVPADHPQMIKAADWML AEQIVRPGDWVVRRPDLPPGGWAFEFHNDNYPDIDDTAEVVLALRRVAHPDATRVDKAVRRA VDWNVGMQSKNGAWGAFDADNTSPFPNRLPFSDFGEVIDPPSADVTAHVVEMLAEEGLAHH PRTRRGIEWLLKNQEGNGSWFGRWGVNYVYGTGAVVPALVAAGLPASHPAIRRSVSWLGQV QNEDGGWGEDLRSYQDSAWHGRGHSTASQTAWALLALLAAGERETEQVRRGIAYLVETQTE DGTWDEPWFTGTGFPWDFTINYHLYRQVFPVTALGRYLNGTGPGEN >seq_ID 123 MQTRDRQTHKPALSLNDAITASQNYLLSLQYPQGYWWAELESNITLTAETVLLHKIWGTDKTRP LHKVEAYLRQQQREHGGWELFYGDGGEISTSVEAYMALRLLGVPSNDPALIRAKNFIISQGGIS KTRIFTKFHLALIGCYSWKGIPSIPPWIMLFPNSFPFTIYEMASWARESTVPLIIVFNDKPVFAIDPI FNLDELYAEGIENVKYELPKNNNWGDLFLGLDKVFKLAEQVDLVPFRKQGLQAAERWMLDHQ QETGDWGGIMPPMVNSLLAFRVLNYDVADPSVQRGFEAIDRFSIEENDTYRVQACVSPVWDT AWCIRALTDSGLPKDHFSLVKAGKWLLEKQVLEYGDWAVKNKTGKPGGWAFEFTNRFYPDID DSATVVMALNGIKLPDEALKQAAINRCLKWIETMQCKAGGWAAFDVDNDQAWLNEIPYGDLKA MIDPNTADVTARVVEMVGSCDLEMSSDRLNKALDYLYEEQEKDGSWFGRWGVNYIYGTSGVL SALAVINPKQHKSQIEQGMNWLLSCQNEDGGWGETCWSYNDLSLKGKGVSTPSQTAWALIGL LDAGEVLNHFETDSIERGINYLLNTQTEEGTWEESEFTGTGFPCHFYIRYHFYRHYFPLIALGRY QQMLGS >seq_ID 10 MTQASVREDAKAALDRAVDYLLSLQDEKGFWKGELETNVTIEAEDLLLREFLGIRTPDITAETAR WIRAKQRSDGTWATFYDGPPDLSTSVEAYVALKLAGDDPAAPHMEKAAAYIRGAGGVERTRV FTRLWLALFGLWPWDDLPTLPPEMIFLPSWFPLNIYDWGCWARQTVVPLTIVSALRPVRPIPLSI DEIRTGAPPPPRDPAWTIRGFFQRLDDLLRGYRRVADHGPARLFRRLAMRRAAEWIIARQEAD GSWGGIQPPWVYSLIALHLLGYPLDHPVLRRGLDGLNGFTIREETADGAVRRLEACQSPVWDT ALAVTALRDAGLPADHPRVQAAARWLVGEEVRVAGDWAVRRPGLPPGGWAFEFANDNYPDT DDTAEVVLALRRVRLEDADQQALEAAVRRATTWVIGMQSTDGGWGAFDADNTRELVLRLPFC DFGAVIDPPSADVTAHIVEMLAALGMRDHPATVAGVRWLLAHQEPDGSWFGRWGANHIYGTG AVVPALIAAGVSPDTPPIRRAIRWLEEHQNPDGGWGEDLRSYTDPALWVGRGVSTASQTAWA LLALLAAGEEASPAVDRGVRWLVTTQQPDGGWDEPHYTGTGFPGDFYINYHLYRLVFPISALG RYVNR >seq_ID 233 MRRRRSPRGPGAGPEADYGPARASAPDRLRGDAARGDAARRVQDATARAIRNLLGRQDPAG WWKGDLETNVTMDAEDLLLRQFLGIRDEAVTQAAALFIRREQREDGTWATFHGGPPELSATIE AYVALRLAGDAPDAPHMATASAWIRAHGGLAAARVFTRIWLALFGWWDWENLPELPPELVLLP PWVPLNIYDFGCWARQTIVPLTVVSAMRPVRPAPFALDELHTDARVPVPPRRMAPPTTWNGA FQWMDRALHVYRRFAPRRLREAAMASAGRWIIERQENDGCWGGIQPPAVYSVIALHLLGYDL GHPVMRAGLESLDRFAVWREDGSRMIEACQSPVWDTCLAAIALADAGVRPDHPALVKAADW MLGEEIVRTGDWAVRRPGLAPGGWAFEFHNDTYPDIDDTAEVVLALRRIRHPDPARVEAAIAR GVSWNLGMQSRGGAWGAFDADNTSPFPNRLPFCDFGEVIDPPSADVTAHVVEMLAAEGRAA DPRTRRGIAWLLAEQEPEGPWFGRWGTNYVYGTGSVVPALTAAGLSPGHPAIRRAVLWLESV QNPDGGWGEDQRSYQDRAWAGKGESTPSQTAWALMALLSAGERDAKTVERGIAYLVETQLA DGGWDEPHFTGTGFPWDFSINYHLYRHVFPLTALGRYLYGEPFGHDGRHIGAHLGDRTGVPA EGV >seq_ID 116 MQTQDRLTQKQPLSLKDAITASQNYLLSLQYPQGYWWAELESNITLTAETVLLHKIWGTDKTRP LHKVEAYLRQQQREHGGWELFYGDGGEISTSVEAYMALRLLGVPQDDPALIRAKDFIISKGGIS KTRIFTKFHLALIGCYDWKGIPSIPPWIMLFPDSFPFTIYEMASWARESTVPLIIVFNDKPVFSVDP VFNLDELYAEGVENVKYELPKNNNWGDIFLGIDQVFKFAEQVDLVPFRKEGLKAAEKWILNHQ QETGDWGGIMPPMLNSLLAFRTLNYDVNDPSVKLGFEAIDRFSIEEDDTYRLQACVSPIWDTA WCVRALTDSGLEKDHFSLVKAGKWLLDKQVMEYGDWAVKNKAGKPGGWAFEFTNRFYPDLD DSATVVMALNGIKLPDEARKQAAINRCLQWIETMQCKEGGWAAFDLNNDQAWLNEVPYGDLK AMIDPNTADVTARVVEMLGSCDLEIESDRLNKSLNYLYKEQEKDGSWFGRWGVNYIYGTSGVL SALAVINPEKHKTQMEQGINWLLSCQNKDGGWGETCRSYNDPSLKGKGVSTPSQTAWSLIGL LDAGEALNKFETDAIERGVNYLLDTQTEEGTWEESEFTGTGFPCHFYIRYHFYRHYFPLIALGR YQNLSSEFGVRS >seq_ID 124 MQIRATVDTAKLEKAIAASQEHLLSTQYPEGYWWAELESNVTMTAEVVLLHKIWKTDGTRPMH KAEKYLRSEQREHGGWELFYGDGGDLSTSVETYTALRLLGVPASDPALLKAKDFILRRGGISKT RIFTKLHLALIGCYDWRGLPSLPPWVMLLPENFPFTIYELSSWARGSTVPLLIVMDRKPVFSVNP QINVDELYAEGRDRVKFELPRKGDWTDLFIELDGLFKFTEQNNLVPFREEGLRAAERWVLERQ EATGDWGGIIPAMLNSLLALRALGYHPADPYVRRGMAAVDRFAIETADTYRVQPCVSPVWDTA LVMRGLIDSGLPADHPAIVKAGEWLLEKQILAYGDWAVKNKTGQPGAWAFEFENRFYPDVDDS AVVVMALQAAQLPDEDLKQQAIERCVKWIATMQCKPGGWAAFDVDNDQDWLNQIPYGDLKA MIDPNTADVTARVLEMIGRSGVTTGEASVERALAYLRREQEVEGCWFGRWGVNYIYGTSGVL AALALIAPKSDHAMIQRGADWLVRCQNADGGWGETCRSYNDPHLKGQGPSTASQTAWALIGL LAAGEATGEFAWGAIDRGINYLLATQQQDGRWDEDWFTGTGFPGHFYLKYHLYQQHFPLTAL GRYSSLTGLKQELKIPLQLKSKPEVVMIEDSDLLSDEDAT >seq_ID 119 MQIQDRNSSPQVTEVLNQVKDAIAASQDYLMSIQYPEGYWWAELESNVTITAEVVLLHKIWGTD KTRPLHKVETYLRRQQREHGGWELFYGDGGDLSTSVEAYMALRLLGVSIDDPALIRGREFILKR GGISKSRIFTKLHLALIGCYDWRGIPSIPPWIMLLPENFPFTIYEMSSWARSSTVPLLIVFDKKPVY CCDPTINLDELYSEGIENVKYDLPKTGDWTDIFVWLDGVFKFAQDYNLVPLRQESLQAAERWV LERQEDSGDWGGIIPAMLNSLLALRALNYEAVDPIVHRGLQSVDNFAIETEDTYHVQPCISPVW DTAWAIRALVESGLKADDPRLVKGAQWLLDKQILDYGDWAVKNKQGTPGGWAFEFDNRWYP DLDDSAVVVMALDQVKMPNEDLKNGAIRRCVRWMATMQCKDGGWGAFDLDNDQNWLNFLP YADLKAMIDPNTSDVTARVLEMLGTCGLIMDSNRVQKAIAYLEKEQEPDGSWFGRWGVNYIYG TSGVLSALAVIAPETHQKELKKGAAWLVGCQNADGGWGETCFSYNDSSLKGKGDSTASQTA WGLIGLLAAGEATGEFFKTAIERGVNYLLKTQREDGTWDENYFTGTGFPCHFYLKYHLYLQYFP LIALSRYQRLLT >seq_ID 9 MSVSERAQPGGNPIPGSTSQSAVKFGRIDAALEDVKRAIAGAKDRVFAQQSKDGWWCGELEA DSMLEADYIFAHTLLGTGDAGKMKRALTEMLRYQNEDGSWSIYPGGPGNISLTVKCYFSAKLM GMTADNPILVKAREWILAHGGVVECNTFTKIYLCFLGQYEYDAVPAIPPEIVLFPNWFYFNIYEIS SWSRAILVPLSIAYAKKPFKKIPPEQGIDELFVGGREKANLHLRWDSKNLLSWRNFFLALDRVTH WFERVHIRPLRSIALKKAEKWMLARFEMSDGLGAIYPAMLNAIIALRCLGYSLDDPQVLRAMDE FEKLGIDEPEGTAEYAEPTFRMQPCVSPVWDTAQAVFALGEAGVPRNDPRMQKAADWLLSKE VRHKGDWAMKVRNAQPGGWYFEFNNEFYPDVDDSAQVLLALNKVDNPRERYQYDVCQRAID WIFAMQCRNGGWASFDKDNTKMIFQYVPFADHNAMLDPPTVDITGRILEMLATYGYTRKDRRV EKAIKFIYDEQEPDGSWFGRWGVNYLYGTFLVLRGLEAIGVWNHEPQIQQAAEWIRSVQNADG GWGETCGSYDDPNTRGVGPSTPSQTAWAILGLLSAGDDRSDSVAKGIKWLLAHQKPDGGWD ESTGSGSKHQALYTGTGFPRVFYLAYHQYRDYFPLLALTNYEKAMERGE >seq_ID 217 MTEEVLQRTAAPAEVLAAAREHLLSLQHERGWWKGELETNVTMDVEDLLLRRFLGILTTAETE QAARWIRSRQRADGTWAQFHGGPGDLSTTVEAYVGLKLAGDDVDSEHMAAARAWILERGGIE ETRVFTRIWLALFGEWSWDDLPAMPPELVLLPPWVPLNLADWGCWARQTIVPLTVVCTLRPR RDLGVGLAELRSGRRRRKVPSPSWAGAFQVLDGALHGYQRHPLRGLREHAMRRAAEWIVAR QEADGSWGGIQPPWVYSLLALHLLGYPLDHPVLRQGLAGLERFLIREETPEGTVRRLEACQSP VWDTVLSMQALRDAGLAADHPALRRAADFVLAEEIRVKGDWSVRRPDLAPGGWAFEFDNDG YPDIDDTAEVVLALNRVDHERPGAVNAAIDRGVRWMSGMQSADGGWGAFDADNTRELVNEL PFCDFGAVIDPPSADVTAHVVEALCVLGRGDGEAVRRGVRWLLDHQELDGSWFGRWGANHV YGTGAAVPALVRAGLRRDHLALRRAVRWLEVHQNDDGGWGEDLRSYDDPVWVGRGRSTAS QTAWALLALLAVDLHDTDAVRRGVGFLAETQRPDGTWDEPQFTGTGFPGDFYINYHLYRLVFP VTALGRYEQARREQSGGSG >seq_ID 249 MIEKNKVKQSILASQKHLLSLQETEGYWWGQLESNVTITAEIILLHKIWQTDKKIPLNKAKNYLIS QQREHGGWELFYGDGGDLSTSIEAYMALRLLGVSRTDPIMIEAQNFIIKKGGISCSRIFTKLHLAL IGCYSWQGIPSIPSSIMLLPEDFPFTIYEMSSWARSSTVPLLIVFDKKPIFSVNPTINLDELYAEGI NNASFELPRKYDLTDLFLGLDKAFKFAENLNLMPLQQEGLKAAEKWILERQEVTGDWGGIIPAM LNSMLALKCLEYDVADPVVVRGLEAIDRFAIENEDSYRVQACVSPVWDTAWVIRSLVDSGISPS HPAMVKAGQWLLQQQILDYGDWVFKNKFGKPGGWAFEFMNRFYPDIDDTAVVVMALDVVEL PDEDLKGKAIARGMEWIASMQCEAGGWAAFDVDNNQDWLNATPYGDLKAMIDPNTADVTGR VLEMVGCCGLAMDSWRVKRGIDFLVREQEEEGCWFGRWGVNYIYGTSGVILALAVMARESHR GYIERGASWLVGCQNSDGGWGESCWSYNDPSLKGKGKSTASQTAWALIGLLAAGEGTGNFA RDAIDGGVGFLVSTQNDDGSWLEDEFTGTGFPGHFYIKYHFYSQYFPLMALGRYESLLSG >seq_ID 222 MAVRDRVNPKTLEAAIAASQSYLLTQQDETGYWWAELESNVSITSEVVLLHKIWGTDRSRPLE KVETYLRSQQRDHGGWELYFDDGGEISVSVEAYMALKLLGVPMEDPAMVRARQFILEHGGISR TRVFTKLHLALIGCYEWRGIPSLPPWVMLLPEQFPFTIYEMSSWARGSTVPLLIVMDREPVYAV EAGFNLDELYVEGRHRAQFDLPLSNEWTDAFIYLDGLFKFAESTNLVPFREEGIRAAERWILER QEATGDWGGIIPAMLNSLLGLKALDYDVHDPIIERGMAALDAFALETEDQYWIQPCISPVWDTA LVVRGLAESGLAPDHPALVKAGEWLLNKQILDYGDWSVKNPGGLPGGWAFEFDNRFYPDVDD TAVVVMALNEVQLPDEQAKDAAIARAVNWIATMQCRPGGWAAFDINNDQDWLNALPYGDLKA MIDPNTADVTARVLEMIGRCHQTTGKNSVDRALRYLRTEQEPEGCWFGRWGVNYIYGTSGVL AALALIDPQGWQSQIQQAAAWLVSCQNTDGGWGETCASYDNPKLKGQGPSTASQTAWAIMG LLSAGEATSVYAEAAIERGVNYLTTTQKMDGTWDEDYFTGTGFPGHFYLKYHLYQQHFPLTAL GRYQAMLQQKS >seq_ID 186 MRTQDRVQVNSIAEAIAASQKYLLSLQNPAGYWWAELESNVTITAEVVLLHKIWGTDKTRPLHK VEAYLRSQQKQHGGWELFYGDGGELSTSVEAYMALKLLGVPATDPAMIQARDFILQRGGISKT RIFTKFHLALIGCYNWRGLPSLPAWVMLLPNQFPVNIYEMSSWARSSTVPLLIVFDQKPVYQVN PTITLDELYAEGVENVRYELPRSGDWTDLFLTLDEGFKLAESFNFIPFREEGIKAAEKWIIERQEA TGDWGGIIPAMLNSMLALRSLGYDTNDPIVERGLQALDNFAIETVDCYRVQPCVSPVWDTAWVI RALIDSGIAPDHPAIVKAGEWLLQKQILDYGDWNVKNRQGKPGAWAFEFENRFYPDVDDTAVV VMALHAAKLPNEQLKQKACDRALQWVASMQCKPGGWAAFDLDNDQDWLNSVPYGDLKAMID PNTADVTARVIEMLGACNLSIDSHNLERALTYLLNEQEAEGCWFGRWGVNYIYGTSGVLSALAL INPQKYQRHIQQGATWLVGCQNPDGGWGETCFSYNDPSLKGQGDSTPSQTAWALIGLIAAGE ATGNFAHDAIERGINHLVSTQQPDGSWFEAYFTGTGFPCHFYLKYHYYQQYFPLIALGRYQAIK SL >seq_ID 153 MQVQPRIEKKHLDSAIEASQAYLLARQYSPGYWWAELESNVSMTAEVVLLHKIWRTDTGRPLA KATAHLLAEQRAHGGWELFYGDGGDLNTSIEAYMALKLLGLTADHPALARARAFILAKGGISRA RIFTKIHLALIGCYDWRGVPSIPPWVMLLPEAFPVNIYEMSSWARGSTVPLLIVFDRKPVFAVEP AITLDELFVEGRAQARFDLPRSSSDWWANLFVDLDWGFKLAESLGAVPLREEGLKAAERWVLE RQEATGDWGGIIPAMLNSLLALRCLDYDPHDPVVERGMAAVDRFAIETESTYRLQPCVSPVWD TALTMRALVDSGLPPDHPALAAAGTWLLKKQILDYGDWAVKNRTGPPGGWAFEFDNRFYPDV DDTAVVVMALDAVRLADETAKGQAIARAVCWVASMQCRGGGWAAFDIDNDAHWLNSLPYAD LKAMIDPNTADVTARVLEMYGRCRLIPAAAGAQRALDYLRRTQEPEGCWFGRWGVNYLYGTS GVLSALAAFAPAERTAIERAAAWLRGCQNTDGGWGETCGSYVDRTLMGQGPSTASQTAWAL LGLIDASRVARFSDSSALERGLAYLVETQKADGSWDEPYFTGTGFPGHFYLKYHLYQQHFPLS ALGRYRRLLS >seq_ID 122 MQIQARNISTKVTEVFSKVKEAIAASQQYLLSIQYPEGYWWAELESNVTITAEAVLLHKIWGTDT TRPLHKVETYLRRQQREHGGWELFYGDGGDLSTSVEAYMALRLLGVSASDPALVRAKAFILSR GGISKSRIFTKMHLALIGCYDWRGVPSIPPWIMLLPENFPFTIYEMSSWARGSTVPLLIVFDKKP VYQCGITLDELYSEGINHVRYDLPRNGDWTDVFVWLDGVFKFAETNNLIPFRNESLKAAERWV LERQEDTGDWGGIIPAMLNSLLALRALDYEVNDPIVHRGFKSVDNFAIETEETYHVQPCISPVW DTAWVLRALVESGLKPDEPVLVKGAQWLLDKQILDYGDWAVKNKEGTPGGWAFEFDNRWYP DLDDSAVVVMALEQVKMPDEQLKYGAMRRCVRWMATMQCKAGGWGAFDVNNDQNWLNYL PYADLKAMIDPNTADVTARVLEMLGTCELSMDHDRVKRAIAYLEQEQEADGSWFGRWGVNYI YGTSGALSALAAIAPVTHQAQIEKGAAWLVGCQNPDGGWGETCFSYNNPALRGKGDSTASQT AWGLIGLLAAGEATGKFAKTALERGVNYLLATQRPDGTWDESYFTGTGFPCHFYLKYHLYLQY FPLIALSRYQRLLGFN >seq_ID 129 MSLTSDPSPAAPTAEKSPKRPTIPVPATADAYGISRSSPPLPAATGRPQAAGPASAGVATARAR DHLLALQSEEGWWKGDLETNVTMDAEDLFMKQFLGIRGDDETEQTARWIRSQQLADGGWPT FYGGPADLSTTIEAYIALRLAGDAVDAPHMARAAELVRAQGGVAASRVFTRIWLAALGQWSWD DVPVIPPELIFLPSWIPLNVYDFACWARQTIVALTIVGSLRPSHDLGFSIDELKVPAAARKPAALR SWEGAFERLDKLLHRYEKRPIKLLRTLALRRATEWVVARQEADGCWGGIQPPWVYSVMALHL MGYPLNHPVIATAFRGMERYVIRRDTPQGPIRQIEACQSPVWDTALAVVALADAGVPGDHPAM VKAGRWLVDEEVRVAGDWAVRRPELAPGGWAFEFDNDFYPDVDDTAEVVLALRRLLGAGHV APPASRQGRAEAPPVNTVEDADPRLAAAMRAAAARGVDWSVGMRSSNGAWGAFDADNVRT LTTKIPFCDFGEVVDPPSADVTAHIVEMLADLGRSDHPITQRAVQWLLDNQEPGGSWFGRWG VNHLYGTGAVVPALIGAGVPTDHPAITAAVRWLLEHQSPEGGWGEDLRSYTDPAWIGRGELTA SQTAWALLALLAVDPHSLAVKRGVRWLCETQRPDGTWDEPYFTGTGFPGDFSLNYHLYRLVF PLTALGRYVSLTGVATP >seq_ID 164 MHSGRVFLEKENREENRATFHSSPLILVEESLNLPKKVEETIKKAQRYLLSIQKEDGHWVGELF VDVTLACDCIHLMHWRGKIDYKKQLRLVKHIVDRQLPDGGWNIYPGGPSEVNATVKAYFALKLA GFSPDDPLMAKARSTILRLGGIPKCMTYTKLGLALLGVYPWDRLPVIPPEIILFPNWFPFNIYEISA WSRAMLVPLSVIHHFKPTRNLPEKYQLHELFPYGTEHGKFSWLKKGARYLSKQGLFLACDKFL QYWDKTSLKPFRKMALKKAEKWLLERISAGSDGLGAIFPAMHYAIMALIAMGYTEDNPILKKAIA DFEGLEVDDKKNDDLRIQPCLSPVWDTAVGLVALAESGVARNAKELKRAAYWLLDREIKIKGD WHVRNPHPEPSGWAFEYNNVYYPDVDDTLMVLLALRLIDIEDKIRKEEVMQRALRWVISFQCK NGGWAAFDKDVYKKWLEDIPFADHNAILDPPCSDITARALELFGKMGIKKTERFVQKAIAYLKET QENDGSWMGRWGVNYIYGTWQALRGLQAIGENMNQEWILRARDWLESCQNEDGGWGETP ASYDNPQLKGKGPSTASQTAWAVSGIMACGDIFRPSVSRGIKYLCDRQLSDGSWAEEFLTGT GFPGVFYLKYDMYRNAWPLLVIGEYHRQYLKAKEQVSYWVDGTIGRKVKKERLPEI >seq_ID 20 MRTQDRVQVNSIAEAIAASQKYLLSLQNPTGYWWAELESNVTITAEVVLLHKIWGTDKTRPLHKI EAYLRSQQKQHGGWELFYGDGGELSTSVEAYMALKLLGVPATDPAMIQARDFILQRGGISKTR IFTKFHLALIGCYNWRGLPSLPAWVMLLPNQFPVNIYEMSSWARSSTVPLLIVFDQKPVYQVNP AITLDELYAEGVENVRYELPRSGDWTDLFLTLDEGFKLAESFNFIPFREEGIKAAEKWIIERQEAT GDWGGIIPAMLNSMLALRVLGYATNDPIVERGLQAIDNFAIETADCYRVQPCVSPVWDTAWVIR ALIDSGMAPDHPAIVKAGEWLLQKQIFDYGDWNVKNRQGQPGAWAFEFDNRFYPDVDDTAVV VMALHAAKLPHEQLKQKACDRALQWVASMQCKPGGWAAFDIDNDQDWLNAVPYGDLKAMID PNTADVTARVIEMLGACNLSIDSHDLERALTYLLNEQEAEGCWFGRWGVNYIYGTSGVLCALAL INPQKYQRHIQQGATWLVGCQNPDGGWGETCFSYNDPSLKGQGDSTPSQTAWALIGLIAAGE ATGNFAHDVIERGINHLVSTQQPDGSWFEAYFTGTGFPCHFYLKYHYYQQYFPLIALGRYQAIN PL >seq_ID 185 MQTQDRVKVNQVAEAIAASQQYLLSIQNPAGYWWAELESNVTITAETVLLHKIWGTDQTRPLH KVEAYLRQEQRQHGGWELFYGDGGELSTSVEAYMALRLLGVPATDPAMIRAQAFILQRGGISK TRIFTKLHLALIGCYNWRGIPSLPPWIMLLPKAFPVNIYEMSSWARSSTVPLLVVCDRKPVFITDP TINLDELYAEGIDRVRWELPQSGDWTDLFLTLDQGFKWAESLNLVPFREEGIKAAEKWILERQE ATGDWGGIIPAMLNSMLALRCLDYDRSDPIVERGLQAIDNFAIETDNSYRVQPCVSPVWDTAW VMRALVESGFVPDHPAVVKAGEWLLQKQILDYGDWAVKNRQGKPGAWAFEFENRFYPDVDD SAVVVMALHLAKLPNEKIKQAAIARAVNVWIASMQCKPGGWAAFDLDNDQDWLNSIPYGDLKAM IDPNTADVTARVVEMLGACDLSIDSDNLERSLTYLLREQETEGCWFGRWGVNYIYGTSGVLSA LALIDPQRHKLSIERGAAWLLGCQNLDGGWGETCRSYDDPSLKGKGDSTASQTAWALIGLLAA GEATGKLAVKAIEQGIGYLMATQQPDGTWFEANFTGTGFPCYFYLKYHLYQQYFPLIALGRYQ AAIKES >seq_ID 244 MVIAASPSVPCPSTEQVRQAIAASRDFLLSEQYADGYWWSELESNVTITAEVVILHKIWGTAAQ RPLEKAKNYLLQQQRDHGGWELYYGDGGELSTSVEAYTALRILGVPATDPALVKAKNFIVGRG GISKSRIFTKMHLALIGCYDWRGTPSIPPWVMLLPNNFFFNIYEMSSWARSSTVPLMIVCDQKP VYDIAQGLRVDELYAEGMENVQYKLPESGTIWDIFIGLDSLFKLQEQAKVVPFREQGLALAEKWI LERQEVSGDWGGIIPAMLNSLLALKVLGYDVNDLYVQRGLAAIDNFAVETEDSYAIQACVSPVW DTAWVVRALAEADLGKDHPALVKAGQWLLDKQILTYGDWQIKNPHGEPGAWAFEFDNNFYPD IDDTCVVMMALQGITLPDEERKQGAINKALQWIATMQCKTGGWAAFDIDNDQDWLNQLPYGDL KAMIDPSTADITARVVEMLGACGLTMDSPRVERGLTYLLQEQEQDGSWFGRWGVNYLYGTSG ALSALAIYDAQRFAPQIKTAIAWLLSCQNADGGWGETCESYKNKQLKGQGNSTASQTAWALIG LLDALKYLPSLGQDAKLTTAIEGGVAFLVQGQTPKGTWEEAEYTGTGFPCHFYIRYHYYRQYFP LIALARYSHLQAS >seq_ID 109 MDDRHIQSEITFGKIDGIRERIQQAMDAAKRYLFSKQDPEGFWCGELEADTTLQSDYIVMHTLL GTGDPVKMQKAGKQILQHQNPDGGWNIYPDGPSNISAAVKAYFSLKLIGHKPDEPEMTKARE WILAHGGVTACNTFSKMYLCFFGQYDYDTVPAIPPEIVLFPNWFWFNLYEISSWSRGILVPLAIC YAKKPFKKIPDEANIDELFVEGRHANLHLTWDKKPFSWRNFFLVLNNMVHFFERVHVRPLRKLA MKRAEKWMLERLEMSDGLGGIYPAILNSIIALRALGYSTDDPQVIRAMDEFEKLGIEEDDTFRM QPCMSPVWDTAYALYALGEAGVPGSDPRMQKAAEWMLKKQVTHKGDWAVKVRNVQPGGW YFEENNEFYPDVDDTAQVILSLNHVRTSNERYQDDTVKRALDWQLAMQCKNGGWASFDKDN NKMVFQYIPFADHNAMLDPATVDITGRVLEALSHHGYSLKDKVVQRAVKFIQSEQEPDGSWFG RWGVNYIYGTMLCLRGLAAVGVDHHEPMVQQAAEWLRMVQNPDGGWGESVGSYDDPKLRG QGPSTASQTAWAVMGLLAANDLRSDSVTRGIAWLLENQKPNGSWWEKWITGTGFPRVFYLKY TMYAEYFPLIAFAEYLRRLNTPLDEKVKLGPQA >seq_ID 174 MQIQDKITEIAAKTAKAIELSQNYLLSTQYSEGYWWAELESNVTITSEAILLHKIWKTDKKRPLDK AATYLRQQQCPNGAWELFYGDGGDLSTTVEAYMGLRLLGIPANDPALEKAREFILAKGGISKTR IFTKMHLALIGCYDWQGVPSIPAWIMLLPENFPFTIYEMSSWARGSTVPLLIVFDKKPVYKMGFN LDELYTEGVNNVKYELPKNNNWSDVFLWLDGLFKWAEKTDLVPFRQESLKAAEKWVIERQED TGDWGGIIPAMLNSLLALKALDYDVYDPIVARGLKAVDNFAIETDNTYCVQPCVSPVWDTAWVI RSLIESGLNPAHPAMIKAGQWLIDQQILDYGDWAIKNKIGTPGGWAFEFDNRWYPDLDDSAVV VMALELIKMPDENIKTSVMKRAVNWMATMQCKAGGWGAFDIDNDQNWLNSLPYADLKAMIDP NTADVTARVLEMLGTCDVKMGENRVKKALDYLEKEQEADGSWFGRWGVNYIYGTSGALSALA FLEPNQYRQQLQKGANWLSSCQNVDGGWGETCFSYNNPKFKGQGNSTASQTAWALIGLLAV GKVTGNYQREVIEKGVNYLLVTQKENGTWDEDYFTGTGFPCHFYLKYHFYQQYFPLLALGRYR ALI >seq_ID 130 MSLTSDPSPAAPKAAKSSKRVNIPAPATPDAYGISRSSPPLSGGGVSGGGVSGGGAATADGTP PTTQTSVDPDLAAAMTAANQARDHLLGLQSEEGWWKGDLETNVTIDAEHLFMKQFLGIRTEEE TEPIARWVRSQQLADGGWATYYGGPAELSTTVEAYIALRLAGDEPDAPHMAAAAALIRSQGGV AAARVFTRIWLATFGEWSWDDVPVLPPELIFLPSWFPLNVYDFGCWARQTIVALTIVGSLRPVR DLGFSIDEIKVAAPVTPPKPAPLHSWEGAFERLDAILHRYERRPIKVLRTLALRRATEWVVARQE ADGCWGGIQPPWIYSVMALHLMGYPLNHPVIATAFRGMERYIIRRETPEGPTAQIEACQSPVW DTALAVVALSDAGVPADHPAMVRAGRWLVDEEVRVAGDWAVRRPALAPGGWAFEFDNDFYP DTDDTAEVVLALRRLLGGSHVTPGGTVTPSGSVTPGGTAELSPAARDRASRGLAAVDPQLAG AMRAAAARGVDWSVGMRSSDGAWGAFDADNVRTLTAKIPFCDFGEVVDPPSADVTAHIVEML ADLGRSDHPITRRAVQWLLDNQEPGGSWFGRWGINHVYGTGAVVPALIAAGVPADHPAITAAV RWLLEHQSPDGGWGEDPRSYDDPAWIGRGELTASQTAWALLALLAVDPHSKAVKRGVRWLC ETQRPDGTWDEPQFTGTGFPGDFYLNYHLYRLVFPLTALGRYVTLTGVATP >seq_ID 248 MPTSLATAIDPKQLQQAIRASQDFLFSQQYAEGYWWAELESNVTMTAEVILLHKIWGTEQRLPL AKAEQYLRNHQRDHGGWELFYGDGGDLSTSVEAYMGLRLLGVPETDPALVKARQFILARGGI SKTRIFTKLHLALIGCYDWRGIPSLPPWIMLLPEGSPFTIYEMSSWARSSTVPLLIVMDRKPVYG MDPPITLDELYSEGRANVVWELPRQGDWRDVFIGLDRVFKLFETLNIHPLREQGLKAAEEWVL ERQEASGDWGGIIPAMLNSLLALRALDYAVDDPIVQRGMAAVDRFAIETETEYRVQPCVSPVW DTALVMRAMVDSGVAPDHPALVKAGEWLLSKQILDYGDWHIKNKKGRPGGWAFEFENRFYPD VDDTAVVVMALHAVTLPNENLKRRAIERAVAWIASMQCRPGGWAAFDVDNDQDWLNGIPYGD LKAMIDPNTADVTARVLEMVGRCQLAFDRVALDRALAYLRNEQEPEGCWFGRWGVNYLYGTS GVLTALSLVAPRYDRWRIRRAAEWLMQCQNADGGWGETCWSYHDPSLKGKGDSTASQTAW AIIGLLAAGDATGDYATEAIERGIAYLLETQRPDGTWHEDYFTGTGFPCHFYLKYHYYQQHFPLT ALGRYARWRNLLAT >seq_ID 150 MAKGILNKFAVIAGTKKAGPPAGEERTVIAPIKEISGKAVHCSQAVKKAEEYLLALQNPEGYWVF ELEADVTIPSEYIMLQRFLGREISPELGKRLENYLLDRQLPDGGWPLYAEDGFANISATVKAYLA LKVLGHSPQAPHMIRARLMVLSLGGAARCNVFTRILLALFGQIPWHTPPAMPVEIVLLPQWFFF HLSKVSYWSRTVIVPLLLLYAKQPVCRLRPEEGIPELFSTPPDKLRHLDGFQPGYWRKNAFIIFD RLLKRFNRFIPSALHRKAIAEAEQWTRSHMQGSGGIGAIFPAMAYAVMALRVLGCGEGDPDYIR GLQAIDDLLQHRTPQEADPPRTDGTCIDSGMSAAFALTPSAHAAADGTGSSSICQPCNSPIWD TCLSLSALMEAGMPASHPAATQAVEWLLSQQILSPGDWSLKVPDLEGGGWAFQFENTLYPDL DDTSKVIMSLLRAGALENERYRDRIARGVNWVLGMQSSGGWAAFDIDNNYHYLNDIPFADHG ALLDPSTSDLTGRCIELLSMVGFDRTFPPIARGIGFLRSEQEENGAWFGRWGVNYIYGTWSVLS GLRQGEDMQQPYIRKAVGWLASCQNHDGGWGETCYSYDDPSLAGKGASTPSQTAWSLLG LMAAGEVNSLAVRRGVRYLLDHQNQWGTWEEKHFTGTGFPRVFYLRYHGYRHFFPLWALGV YSRLSSGQKACQDERRHASPGDLHLPWLERIKKR >seq_ID 128 MPDLELRDVDRADGRHHAPNLGRTDTLSPSAPTGEPAPASTPAAVATPTPTPTTAPAPAPAPE NALRETVQRAAEHLLRLQDPRGWWKFDLETNPTMDAEDLLLREYLGIRTVEQTEATAKHIRSR RLDDGSWPTYFGGPGELSTTVECYIALRLAGDSPDDEPLRRSAAWIRERGGIPATRVFTRIWLA LFGWWRWEDLPVLPPEIMFLPPRAPLSIYSFASWARQTIVPLTIVSAARPQCPAPFDLAELDPD EVPAAQSHGAAQSPDTRSPAGGRTLRGAMRRLGGDRPNTAKVFFRGLDAALHRYHRHPIGPL RRHALRTAERWIIARQEADGCFGGIQPPAVYSIIALRLLGYDLDHPVLAAALRSLDAYTLHREDG SRMIEASQSPIWDTALAVLALADAGIDAPADVDVAPALPTQRVATGAPAPSAPVPTALERAADW LLGQEIQHRRGDWAITHPGVAPGGWAFEFDNDTYPDTDDTAEVVLALHRLNRLRRLRHPTNTR IDAALERSTAWLFALQSRDGGWGAYDSDNASTLVYQIPFADFGALTDPSSADVTAHVVELLCE TGRIRDPRTLRGVDWLLRNQEADGSWYGRWGVNYVYGTGSVLPALQAAGLPPTHPAMVAGA RWLLSRQNSDGGWGEDIRSYGDPAWSGRGLSTPSQTAWAMLGLLATDHGGVHADALAAAA RWLTEQQRPDGGWDEEMFTGTGFPGFFYLNYHGYRLVWPVMALGRYLHSRQHPSD >seq_ID 131 MSLTSDQSSAAPTAAAQSPKIPNPSVARPSADAGSFETAGAVRTDSVSIDSVSTGTPVDPVVG AMRRGRDHLLSLQAEEGWWKGELETNVTMDAEDLMLRQFLGILTPSTATETGRWIRSQQLSD GGWATFYGGPSDLSTTIEAYVALRLAGDDPDAPHMRSAAEWVRSAGGIAASRVFTRIWLALFG EWSWDDVPVLPAEMTFLPPWFPLNIYDFACWARQTVVALTIVGSLRPVRSFGFTLDELRVQAP KATKAPLRSWAGAFERLDSVLHRYEKRPFQPLRRLALRRAAEWVIARQEADGCWGGIQPPMV YSIMALHLMGYPLNHPVISMAFRALDRFTIREETPEGTVRRIEACQSPVWDTALAVVALADAGL GGDHPAMVRAGRWLADEEVRVAGDWAVRRPTLAPGGWAFEFDNDFYPDVDDTAEVVIAIRR LLGDGHGPVDHSDGSGPGSAAATAASAAAEAAVAAAGTIAAADPELAARLRAAAERGVDWSV GMRSSNGAWAAFDADNVRTLVRKIPFCDFGEVVDPPSADVTAHMVEMLALLGRSDHPITQRG VRWLLDNQEAGGSWFGRWGVNHVYGTGAVVPALISAGVDAEHPAIVSSMHWLVEHQTPEGG WGEDLRSYRDDEWIGRGEPTASQTAWALLALLAAEPASGTAEWEAVERGVRWLCDTQRPDG TWDEPQFTGTGFPWDFSINYHLYRLVFPVTALGRYVTLTGRSTS >seq_ID 242 MSISALQTDRLSQTLTQSVVAAQQHLLSIQNPEGYWWANLESNASITAEVVLLHKIWGTLDSQP LAKLENYLRAQQKTHGGWELYWNDGGELSTSVEAYMGLRLLGVPASDPALVKAKQFILHRGG VSKTRIFTKFHLALIGCYRWQGLPSLPAWVMQLESPFPFSIYELSSWARGSTVPLLIVFDKKPVY PLQPSPTLDELFTESAENVRWELEEKGDWSDAFLWLDKAFKLAESVDLVPFREESIRKAEKWV LERQEPSGDWGGIIPAMLNSMLALRALGYSVSDPVVRRGFQAIDNFMVESETECWAQPCISPV WDTGLAVRSLTDSGLSPNHPALVKAGEWLLDKQILSYGDWSVKNPQGQPGGWAFEFENSFY PDVDDTAVVAMALQDITLPNEPLKRRAIARAVRWIATMQCKTGGWAAFDINNDQDWLNDIPYG DLRAMIDPSTADITGRVLEMHGRFAADLDLANSYAADLSPYRLSRGLNYLIKEQELDGSWFGR WGVNYIYGTGQALSALALIAPERCRIQIERGIAWFVSVQNADGGWGETCESYKDKSLKGKGIST ASQTAWALLGLLDVSFCLDPAAKIAVDRGIQYLVSTQSEGTWQEESFTGTGFPQHFYLRYRLY CHYFPLMALGRYQRVINSSAGI >seq_ID 143 MAKGILNKFAVIAGNKNAGLTAEEECTVVAPIKEVSGKAVHCRQAVKMAEEYLLALQNPEGYW VFELEADVTIPSEYIMLQRFLGREISPELRMRLENYLLDRQLPDGGWPLYAVDGFANISATVKAY LALKVLGHSPQAPHMIRARIMVLSLGGAARCNVFTRILLALFGQLPWHTPPAMPVEIVLLPQRFF FHLSKVSYWSRTVIVPMLLLYAKQPVCRLRPEEGIPELFNTPPDKLRNLDGFQSGRWRKNAFIII DRLLKRFNRFIPSAIHRKAMAEAEHWTRSRMQGSGGIGAIFPAMAYAVMALRVLGCREDDPDY VRGMQAIDDLLQHRTPQEADSPRTGGPCIDSGTSAAFAFDPSPHAAADGRGNSSICQPCNSPI WDTCLSLSALMEAGMPASHPAAKQAVEWLLSQQIFSPGDWSLKAPDLEGGGWAFQFENTLY PDLDDTSKVIMSLLRAGALENGLYRDRVARGVNWVLGMQSSDGGWAAFDIDNNYHYLNDIPF ADHGALLDPSTSDLTGRCIELLSMVGFDRTFPPIAQGIGFLRSKQEGSGAWFGRWGVNYIYGT WSVLSGLRQAGEDMQQPYIRRAVGWLTSCQNHDGGWGETCYSYDDPSLAGQGESTPSQTA WSLLGLMAAGDVHSLAVRRGVRYLLDHQNQWGTWEEKHFTGTGFPRVFYLRYHGYRHYFPL WALGVYSRLSSGQKTRQEERRHSSPGDLHLPWLERIGRR >seq_ID 71 MIKNFTALWPIRRVKGVSVTSQDGHSANGASKPDFEVRPHVDLETAIHRSQSFLLKEQKPEGY WVGELIVDSTLVSDTIAYHHWNGKVDMEWQRKAVNHIFSMQLPDGGWNIYYGGPAEINATVKA YLALKLAGVPVMDPRMLRARSVALSMGGVPRMNTFSKLYLALLGLFPWNYVPTIPCEVILIGKW FHVNFYEMSSWSRSMLVPLAIINHFKPTRKLQNQVKLDELYPEGYHERDLALPPDPEFLTFRNF FLWLDKLHKFAELWVQAGIHPFRRRALKKCEHWMLERFEGSNGLAAIFPAMLNSLIALKALGYP GDHPEVKRAEKELKNLEHETADTVRIEPCFSPVWDTAIVAICLHESGIPSDHPALKKSAEWLIDK EIRFRGDWYFKNPVDVEPSGWVFEFENKWNPDVDDTAMVLLALRKIPTSDVKRRDECFQRGL KWMMAFQCKDGGWAAFDKDCTKGILEKVPFADHNAMLDPECADITARILELLGYEGVGVDHP QIKKALQFIQEEQEDDGSWYGRWGVNYIYGTWQVLRGLRALNINMNQPWLLKARDWLESVQH EDGGWGERCNTYDDPVFKGQGPSTASQTAWAVMGLCTFDDPQRPSLMRGIDYLIKTQNSDG SWTEHEITGTGFPRVFYLKYDMYRNSWPLLALATYRNLYASSEKTANGHTNGHSVQLPEALKT PPAFK >seq_ID 126 MNKKSAMKLKKKAKNHVVSLLQPTDALNRVMKRFRSLQSPEGYWVFALEADVTIPSEYIMFNR FLGRKMDKGLAERLGNYIRAKQMADGGWPLHDNDGPVNISASVKAYMALKMLGDNKDAEHM VRARQIILAKGGAETANVFTRICLATFGQIPWHCPPAMPIEIVLLPKWFFFHLDKVSYWSRSVIYP LLIIYAKQPVCRLRPEEAVPELFCKPAEEHIHIDKYRDKGWRKNLFILLDRVLKRTIHLVPKSINKK ALNYAEKWTREHMAGRGGIGAIFPAMANAVMALSLLGYDESDPDFARGMQSVDDLMVDKFHV PEKSPWEHTVITGGAELSAAPELDISPDHGTAENLEQAMCQPCNSPIWDTCLTLSAMMEAGEN QDSKSTQQALNWLWDQQIFFRGDWISKAPKLEGGGWAFQFENTFYPDLDDTAMVLMAMCRA GVLDQPEHRENFIKGVNWLIGMQSSNGGWAAFDIDNCAEYLNDIPFADHGALLDPPTSDLTAR VIELLGVLGYDKSFRPIKDGIEFLKKEQEDDGSWFGRWGVNYIYGTWSVLCGLRQAGEDMNSS YVCKAVEWFENHQNKDGGWGESCLSYNDKNYAGLGDSTASQTAWALLGLMAAGRVHSKAV SRGVRYLLDTQKDDGSWDESLFTGTGFPRVFYLRYHGYSQYFPMWALGVYQRFSADEDTKQI MMRRKSPLDLGRKW >seq_ID 114 MIFTDTPTGSTQNRLDVAIRRAQQNLLRLQHNEGYWCGELFVDSTLCSDYVLFMHWADEIDPV MEEKCVAHIRRRQLEDGGWNIYEGGPSDVNATVKAYFALKLAGHAPTQPWMQEARACILRLG GIPKMNTYAKLYLALLGQFPWRYLPTVPVEIMFMPRWFFFDIYEVSSWSRAMLMPLAILNHYKP TKHLPADKQLHELYPIGSEESDLGLGMQKPRFSWPNFFLFCDRLIKIMHSLPWKPWKRAALAR AEAWMTQRMGEGSDGLAAIFPAMLNSMIALRTLRYSREHPLYVKAKNDFAGLFVDDPQDFRIQ PCLSPVWDTAINLVALLESGLDPHDPKIEAAVNWLKEKEVRINGDWYVKNHHVPPSGWAFEFN NVYYPDTDDTMMVLAALARAGAHEESAPVETKAMFERALKWLLSFQCRDGGWAAFDKDVTQ GWLEDVPFADHNAILDPTCSDLTGRVLELLGLIDYDRNCTPVRRALKFLRDTQEDDGSWYGRW GVNYIYGTWQVLRGLRSIGEDMRQQWIVRARDWLESCQNEDGGWGETCASYDDPTLKGKGP STASQTAWALMGLIAAADPTEPGAFDRKSIRQGVDYLLSTQVADGSWVEPEVTGTGFPRVFYL RYDMYRNNFPLMALATYRKAREGKLPVRQRE >seq_ID 194 MKKATRSVFSLLDGGKISDSGSRGDSRHAGSRLDSVTKSAAALLASRQNPDGHWVFDLEADV TIPAEYVMMRCFIGEPLDSDMASRLSAYLLERQLPDGGWPLYAVDGNANISATVKAYFALKLLG HDKYAPHMVSARRMILAQGGAERSNVFTRITLALFGQVPWHTTPAMPIEIMLLPKWFFFHLSKV AYWSRTVIVPLLILYNKQPVCRLGYSEGIAELFSTSPDMLVHLDHFRYRAWRKNAFIVLDRLLKR TMHLVPGRIKRRALEEAERWTRERMKGDGSIGAIYPAMANAVMALKTLGCGDSDPDYLRGLR AIDRLLIHGKPEAGALPADGAGTLFPVLDGASSAAVDLYPASLSDTAKSHAFSFCQPCNSPVWD TALSLTALSEAGGGGYSPERAMEWLFNRQIATQGDWTERCPGLECGGWAFQYENALYPDVD DTAKVLMSLFRAGALERGEYPEKIAKAVRWVLGMQGADGGWGAFDVDNNHFYLNDIPFADHG ALLDPSTADLTGRCIEMLGMLGHGPDYPPITRGIEFLREEQEPFGGWFGRWGVNYIYGTWSVL SGLSQAGEDMGRPYVRKAVEWLVSCQNDDGGWGETCASYDDPSLAGSGASTASQTAWALL GLMAAGEADHAAVRAGIAYLADSFADGWDERHFTGTGFPRVFYLRYHGYSLFFPVWALGVYA RHREGGKTVQEQVRERGVNGVFDFVMGGSA >seq_ID 154 MMANATDTIELPPSRAADRIVPMTDIDQAVDAAHAALGRRQQDDGHWVFELEADATIPAEYVLL EHYLDRIDPALEERIGVYLRRIQGDHGGWPLYHGGKFDVSATVKAYFALKAIGDDIDAPHMARA RAAILDHGGAERSNVFTRFQLALFGEVPWHATPVMPVELMLLPRKALFSVWNMSYWSRTVIAP LLVLAALRPRAINPRDVHVPELFVTPPDQVRDWIRGPYRSQLGRLFKYVDIALRPAERLIPDATR QRAIKAAVDFIEPRLNGEDGLGAIYPAMANTVMMYRALGVPDSDPRAATAWEAVRRLLVELDG EAYCQPCVSPIWDTGLAGHAMIEAASGPEGIRPEDTKKKLAAAAEWLRERQILNVKGDWAINC PDVPPGGWAFQYNNDYYPDVDDTAVVGMLLHREGDPANDEALERARQWIIGMQSSNGGWG AFDIDNNLDFLNHIPFADHGALLDPPTADVTARCISFLAQLGHPEDRPVIERGIAYLRTDQEREG CWFGRWGTNYIYGTWSVLCAYNAAGVAHDDPSVVRAVDWLRSVQREDGGWGEDCASYEGA TPGIYTESLPSQTAWAVLGLMAVGLRDDPAVMRGMAYLTRTQKDDGEWDEEPYNAVGFPKVF YLRYHGYRQFFPLLALSRYRNLASSNSRHVAFGF >seq_ID 156 MLIYSDILEKEDRVSETLSRQSVEPDEINHAIEGAQAALGGKQKSDGHWVYELEADATIPAEYVL LEHYLDRIDPEKQAKIGVYLRRIQGHHGGWPLYHDGGFDLSATVKAYFALKAIGDDINAPHMRIA REAILDHGGAARTNVFTRIQLALFGEVPWDATPVMPVELMLLPRKAFFSVWNMSYWSRAVIAP LLVLNALRPKAINPRGIHVQELFVKPPSEVKDWIRGPYRSVWGRFFKHLDSALRPVLPLIPRSVH KKALKAASDFIEPRLSRGGLGAIYPAMANVVMMYRAQGVPDSDPRAKTAWDAIQDLLVDHGDE IYCQPCVSPVWDTGLSGLAMIEAASGPAGTKTKETLAALKKSAEWLREHQILDVKGDWAINAPD LRPGGWAFQYENDYYPDVDDTAVVAMLLHRVDPENSREAISRAREWIIGMQSTNGGWGAFDI DNDHELLNHIPFSDHGALLDPPTADVSARCISFLAQLGDPDDRPVILKAIEYLRSEQEPEGCWF GRWGTNYIYGTWSVLCALNIAGVPHDDPMVLRAVNWLESVQRPDGGWGEDCATYEGGTAGT YKKSLPSQTAWAVLALMAVGRRESEAVKRGVAYLVSQQNEKGEWQEEAYNAVGFPKVFYLR YHGYKQFFPLTALARYRNLGVSNSGKVEYGF >seq_ID 74 MEGASPTASNRISQYAVDLRAKARAAVASTCDWLLSHQHADGHWCAELEGDSILQSEYILLLA WLGKERTEIARRCAAHLLKQQEPNGAWTQFPGAPIDVGSSVKAYFALKLTGHDAAADYMVRA RNAILEAGGADKVNSFTRFYLALLGQIPFELCPAVPPEMVLLPNWSPINIYRISSWSRTIFVPLSIV WAHRAARDIVEDVSIHELFIRKPEDWPELRCPGLEKPAGLFSWDRFFRTADSGLKLLEKYGLRP LRKRALRQAQQWMLDRFQQSDGPGAIFPPIVWSAIALRTLGYAEDSPEIQYCLDHLERLVLEDG ETTKLQPCKSPVWDTSITLRALAAAGLGLAQEPTCRGVEWLLSKEVRVPGDWTNNVDCEPGG WFFEYENAFYPDNDDTSMGIMALADQLAAANITLEVHPGETLANTSVVVGGRGIAEQLAGSSA AMMEQAAAATRRAVAWMVAMQNKDGGWGAFDKNNDAEFLCHVPFADHNAMIDPSTPDLSA RVIESFGRLGVTIESPGKLGDTVRRAVAYIRANQLSDGSWFGRWGVNYIYGTWQCLVGLRAVG VPANDPAIEQGKLWLLAHQQACGGWGESCETYEDPSLRGQGSPTASQTAWALLGIIAAGGAN LAEVVHGVQYLMDTQREDGAWDEIEFTGTGFPRVFYLKYHYYPIYFPLLALAEWNRATARS >seq_ID 326 MFDTISFDFDALDQAISRAHARLSAEQRADGHYVYELEADATIPAEYVLLEHFLDRIDPELEARIG VFLRGIQGNSPQNPGGWPLFHDGAMDISASVKAYFALKAIGDDPDAPHMRRAREAILARGGAA RTNVFTRIQLALFGAVPWRACPVMPVEIMLLPDWFPITIWKISYWSRTVIAPLLVLLTERPIARNP RNVRIDELFVTPPDQVTDYIRGPYRSNWGYLFKAIDSALRPLERHFPARSRKRAIQAAIDFITPRL NGEDGLGAIYPAMANTVMMYHTLGYSPDHPDYATAWASVRKLVTDASYRFEGASYVQPCLSP VWDTSLAAHALAEAGSPGDAQLAAACDWLIPRQILDVKGDWAYRKPDAPPGGWAFQYNNAH YPDVDDTAVVGMILDRNGDPAHREAVERARQWILGMQSRSGGWGAFDSDNEFHYLNHIPFAD HGALLDPPTADVTARCISFLAQLGHAEDRPAIERGVAYLRREQEQDGSWFGRWGTNYIYGTW SSLCALNAAGVAQDDPMMVRAVEWLLARQRPDGGWGEDCETYAHAKPGEYHESLPSQTAW ALLGLMAAGQAEHEAVARGIAWLQSVQEDDGSWTEQPYNAVGFPRVFYLRYHGYPRFFPLLA MARYRNLARGNSRQVQFGF >seq_ID 192 MDKIKMKNINQPKFRVFRGGQKAATPCPGTTNERRGALDRGRLSASLKHSREWLLSLQADAG NWVFALEADTTIASEYVMLQRFLGRPLAPELQQRLANYLLSRQLPDGGWPLYAEDGFANISTT VKAYLALKLLGYPTHCDPLVRARQIVLALGGAEKCNVFTRIALALFGQIPWRTTPAMPVEIMLLP RWFYFHLSKISYWARTVVVPLLILYAKRPVCRLEPWEGIPELFVTPPDKLGYLDVCKPGQWRKN VFIWVDRLTRKMVRCVPRRLHNLALRAAETWTREHMQGAGGIGAIFPAMANAVMALRTLGCS PDDADYQRGLKALDDLLIDRCDVPPREDTPVSPCWCTGTSAAPMLDPSPAGSHAQGGDQGIC QPCASPIWDTGLALTALLEGGLDARHPAVDRAVRWLLDQQVDVKGDWAQRVPNLEAGGWAF QFENALYPDLDDTSKVLMSLIRAGAMDNPGYRQELSRAINWVIGMQNSDGGWGAFDVDNNYL YLNDIPFADHGALLDPSTADVTGRCIEMLAMAGFGRDFLPIARGVDFLRREQEDFGGWYGRW GVNYIYGTWSALSGLIHAGEDLQAPYIRQAVGWLESVQNPDGGWGETCYSYDDPALAGRGVS TASQTAWALLGLMAAGEVDNLAVRRGIQYLVEEQNRAGGWDERHFTGTGFPRVFYLRYHGYS QYFPLWALGLYERLSSGNPSRQQMVRRAGPAGLHLPVLDRRKKLRRKRKA >seq_ID 72 MKSEEVTIKPAVGLEKDELNAAITRSQSFLLCEQKPEGYWVGELMVDSTIVSDTIAYHHWNGKV DPEWQRKAVNHILSMQLPEGGWNIYQNGPPEVNATIKAYLALKLAGIPITDPRMLKARQVALTL GGVPRMNTFSKLYLALLGLWPWKYVPTIPCEVLLLGKWFHVNIWDMSNWSRAMIVPLAIINHYK PTRPVKVDLSELFLEGFHERDLALPKDPQSFTWRNFFLGLDQLHKFAELWVNAGIHPFRRLALK KCEQWMLERFEGSDGLAAIFPAMLNSLIALKSLGYPDDHPEVLRAERELKKLEHETKDTVRIEP CLSPGWDTAIAAMCLRESGVPAEHPRLKKAGDWLVNREVRFKADWHHKNPVDVEPSGWVFQ FNNKWNPDLDDTAMVLLALRLIPTDHPRRRDEAFQRGLKWLLAFQCRDGGWAAYDKDCTKNI LEKVPFADHNAMLDPECADITARVLELLGFEGYALDHPQVQEAVEYLREHQETDGSWYGRWG VNYIYGTWQTLRGLWALKMDMNQPWLLKARDWLESVQLPDGGWGERCNTYDDPVFKGQGP STASQTAWAVMALCTFGDPKRPSLVRGIQYLIENQNEDGSWTELETTGTGFPRVYYLKYDIYR NTWPLLAMATYRKMLDPKEVRVK >seq_ID 145 MNKHKGTFSVIEGGKTTQARGSETCAIMDAADLEKVTSVAASQLAGQQQDDGHWVFDLEADV TIPAEYVMLQRFIGREIDPEISERLAAYMQERQLPDGGWPLYAVDGNVNISASVKAYFALKLLGH DKNAPHMVRARQLILSLGGAAKCNVFTRITLATFGQIPWHTAPAMPIEIMLLPRWFFFHLNKVAY WSRTVIVPLLILYATQPICRLQYNEGITELFTTPPDMLVHLDKFRHHAWRKNVFIALDRVLKRTM HLVPGRIKQHALAEAERWTRARMQGDGGIGAIYPAMANAVMALKTLGCSDDDADYLRGLEAV DNLMVHRNLKTGTIPMDDDSGGIAIDNSSAAPELSPTYLTDTAGNTEFSFCQPCNSPIWDTCMS LSALCESGYAENNSGVTDRAIKWLFSQQIATPGDWSEKCPGLESGGWAFQYENSRYPDVDDT AKVLMSLFRAGALEKPEYREKIERAIRWVQGMQSTDGGWGAFDVDNDYFYLNDIPFADHGALL DPSTADLTGRCIEMMGMLGHGPDYPPIARGIAYLKKEQEPFGGWFGRWGVNYIYGTWSVLSG LHQAGENMDAPYVRKAVEWLISCQNSDGGWGETCASYDDPSLAGSGASTASQTSWALMALM AAGEWRHSAVRNGVRYLTESYCNGWNEKQFTGTGFPRVFYLRYHGYSLFFPVWALAVYSRYI NGTATVQEKVREKQFRQCLMV >seq_ID 127 MLPYNQDFYNEDEALKDDHCEGAGNVSNPPTLDEAIKRSQDFLLSQQYPEGYWWAELEGNPT ITSHTVILYKILGIEDEYPMDKMEKYLRRMQCIHGGWELFYGDGGQLSVTIESYVALRLLNVPPT DPALKKALKFIIDKGGVXKSRMFTKICLALLGCFDWRGIPSLPPWVMLLPGWFLSSIYETACWA RGCVVPLIVVFDKKPVFKVSPEVSFDELYAEGREHACKTLPFCGDWTSHFFIAVDRVFKMMER LGVVPFQQWGIREAEKWLLERQEDTGDFLGVYPPMFYSVVCMKTLGYEVTDPVVRRALLSFK KFSIERADECSVQSSLSPVWDTALVVRSLVESGLPPDHPALQRAGEWLLQKQITKHGDWSFKN QSGVAGGWAFQFFNRWYPDLDDSAVVVMALDCLKLPNEDVKNGAITRCLKWISSMQCKGGG WAAFDKDNHQHWINSTPFSDLKAMVDPSTTDISARVLEMVGRLKLHGTSFDEAHFLPPESIAR GLVYLRREQENEGCWFGRWGVNYIYGTCGALVALSLVAPMTHEEEIARGARWLVQVQNMHG KKINGPQDGGWGETCFSYNDPALKGQGDVSTASQTAWALQGLLAAGDALGKYEVESIGHGV QYLLSTQRKDGSWHESQFTGGGFPIHFYLRYHFYAQHFTLSSLARYRTRLQASKIKPPIP >seq_ID 166 MNTEPRFSAPETLRAIAGAGRALGRHQRRDGHWVFELEADATIPAEYVLLEHYMDRITPERQA RIGAYLRRIQGEHGGWPMFHAGEFNISASVKAYCALKAIGDDPQAPHMVRARQAILGHGGAER ANVFTRIQLALFGAIPWRGVPVMPVEIMHLPKWFFFNIWAMSYWARTCVVPLLVLQARKPRAR NPRQVSFDEIFRTEPDEVRDWIRGPYRSRWGVVFKHIDTVLRWTEPLFSKVARESAIFKAVDFV EERLNGEDGLGAIYPAMAYALMMYDVLGYPEDDPRCVTIWKAIDKLLIETDEEVYCQPCVSPV WDTSLSGHAMIEAARTGGIEAQAELDAACDWLVARQVKDVRGDWAETRPDAEPGGWAFQYR NDHYPDVDDTAVVAMLLHRNGRPEHAEAIEKARRWVVGVQSRNGGWGAFDADNDREFLNHI PFSDHGALLDPPTADVTGRCISFLSQLGHEEDRPVIERALAYLRAEQERDGSWYGRWGTNYV YGTWTVLCGLNAAGIPHDDPMVRRAVDWLVSIQRADGGWGEDERSYDVGHYVENAESLPSQ TAWAMLGLMSVGQADHPAVLRGAAYLQRTQGPDGEWQERAYNAVGFPRVFYLKYHGYRLFF PLFALSRLHNLQRGNSREVSFGF >seq_ID 21 MSGEVRVAGDALAEDAGRAAAAASQYLYRTQQRDHWRAELESNVTVTAEYVLLRQALGLDLE ERRDALVRYLCSRQKADGSFGIASTLPGDVSTTAEAYLALRLLGLDREDERLRAAERFIRGAGG LARVRVFTRINLALFGLFPWEAVPTVPAELIFLPRWAPVNVYRLASWARSTMVPLFVLFHHRPV FALPGGAGSDWLDHLWLGPGDKRVPYRTSVMETVRRHGPGWKAFFNAADAWLRVHDRLRH LPPLGRLRTEALRACEEWILARQEASGDWAGIFPPMLNGVLALHVAGHGLDAAPVRRGLEAIE RFAVSDREGFRIEACQSPVWDTILALIGLLDSGESPTDPRLVAARRWIEGMQLTNDWGDWKVY DPRGEPGGWAFEYANSWYPDVDDTAAVIVGLLKHDPASRAGETVRRAAAWVASMQNRDGG WAAFDNNNDRLFLNEIPFSDMDSLCDPSSPDVTGRVLEAFGMLDAPHLRAACRRGVAYLRRA QEPEGSWYGRWGVNYVYGTSNVLNGLARQRVPASDPMVARALGWLDSVQNADGGFGEGLE SYADRAAMGRGPSTASQTAWGVMGLLAYRAADDAAVRRGIAWLVERQLADGEAQGSWEEE AFTGTGFPRHFYLRYHLYRHYFPLMALGRFCAQGRG >seq_ID 111 MSYEWTEPVRPGRRHAVSPVQNFCQSLAPAIQRACDALFSQQAADGFWCGELTADTTLESDY ILLQLWLNQPDDHGWNPPTRPRIDRAGRSILERQLPDGGFNIYAGGPSEVSATIKAYCALKLAG LDPHSPPLRRARERILALGGLQAANSYVKINLSLFGLYPRKHVPSVPPEIVMLPGNVLYEMSSW TRSILVPLSIVQARGSNRRAPNGFNLDELLLPGVKLALPKRKGLAVLFHHLDRMFKVWEKRGSE RIRGAAIREAERWLIARTHYTEGLGAIYPAMMYFIMALDALGYAEDHPDRSEAIRHFESLLIETDD RFLFQPCVSPVWDTAICAFALGEAGNTDDPRMTLAADWLISKEVRRKGDWSIKRPDTEPSGW AFEFANEFYPDIDDTAMVLLALMHANGSNPEAQAAAERRAVNWLLAMQSSDGGWAAFDVDN NWAMLNQVPFADHNAMLDPTCPDITGRVLECLCRRGMAGHDAARRGVAYLLQAQEKDGSWY GRWGVNYIYGSFLAMRGLTTSGAPGSQDAVDRAARWLRAIQNPDGGWGESCASYARDGYVA APSSASQTAWALLGLCAAGDRDSAQFRRGVEYLLTLQAPDGKWPEGATTGTGFPNVFYLTYA MYRDYFPLLALSQV >seq_ID 157 MPKDIPADLASEAISGDMLEQAVLRASMALHRKQQTDGHWVFELEADATIPAEYVLLEHFLDRI DDDLERKIGVYLRRIQGDHGGWPLFHEGAFNLSASVKAYYALKAIGDDPDAPHMRRAREAILAA GGAERSNVFTRIQLALFGQIPWRGVPVMPAELMIAPKWFPINMWKVSYWSRTVIAPLLVLMDR KPKARNPRNVHVRELFLHDPDRIRDWIRGPFRSGWGHFFKYLDSVLRVVEPVALKPMRPRSIR LAVDFVRERLNGEDGLGAIYPAMANSVMMYDVLGYSPDHPEAAIAWESVRKLLVIKEDEAYCQ PCLSPIWDTGLSGHAMAEAEGAVSPGVAAACDWLRNRQITDVVGDWAEIRPGVQPGGWAFQ YNNAHYPDVDDTAVVAMLLHRQGDPAHEESIRKAREWIIGLQCRDGGWGAFDADNDKDYLNH IPFADHGALLDPPTADVTARCISFLAQLGNPEDKPVIDRAMAWLRKEQEADGSWFGRWGTNYI YGTWSVLCAMNVAGMPHDDPAIRRAVNFLVATQREDGGWGEDEETYDPASGAQPGRYKEST PSQTAWALIGLMAAGEAEHEATRRGIAYLQATQKPDGEWDEAAYTAVGFPRVFYLKYHGYRQ FFPLMALSRYKNLRSSNMKKVSFGF >seq_ID 205 MNQAATITRPQDETLTTSARRPAQPALPDPLDAGIAHVVESLLAQQQSDGHWVYELEADATIPA EYILMVHYLGETPDLVLEGKIANYLRRIQNADGGWPLFHAGASDISASVKGYFALKMAGDNPEA EHMRRARAAIHAMGGAEASNVFTRTLLALYGVMPWQAVPMMPVEIMLLPEWFPFHLSKVSYW ARTVIVPLLVLNSLRPQARNPRKIGIDELFVRPCQATRLPRRAPHQSPLWVGVFRTLDAVVRMA EPLFPRGLRQRAIERAREFTVERLNGEDGLGAIFPAMVNSVLMFDVLGVPESDPNRAIARRSID KLLVIKDDEAYCQPCLSPVWDTSLAAHALLEVGEPRTIAAAARGLDWLLPLQELELRGDWTVRR PNVRPGGWAFQYANPHYPDVDDTAVVAAAMDRVDKGDRSNRYDEAVSRACEWIVGMQSSN GGWGAFEPENTHLYLNNIPFADHGALLDPPTADVSARCLAMLCQLGQMPANSEPAARALRYLL DEQEADGSWFGRWGTNYIYGTWSALCGLNAAGIGTDAPEMKRAAQWLLSIQNEDGGWGESG DSYKLEYRGYEKAPSTASQTAWAMLGLMAAGAGDHPALVRGVEYLLRTQASHGFWNDEPYFT AVGFPRVFYLRYHGYSRFFPLWALARFRNLLRDGNRAISWGL >seq_ID 218 MKTDGNTTLDTTISMEELERTVKSAYEALAKDQQDDGHWIYELEADVTIPAQFILLEHTLDKIDE ELEQKIANYLRRCQSREHWGWPVYYGGEFNISASVQAYFALKMTGEDINAPHMVRAREAILAH GGPEYANVFTRIQLSLFGEASWLATPFMPVEIMLLPRWMYFSIWNMSYWSRTTVAPLLIVADLK PKAINPRNVHIPELFPTPPDKVKTWIHGPFRSKWGHVFKFIDTAIRPFTRFVPSFLHKKAYKAAL DFIEPRLNGVDGLGAIYPPMSYSAVMYRALGIPDDDPRAATNWEALKGLLVIKEREAYCQACVS PVWDTALSGHALMEASFGPDGINADRTEKLIDRAAHWLRAHQVLNVVGDWAINNPNLQPGGW AFQYGNDYYPDVDDTAVAAMLLHRQNLPENEEALDRARKWIIGMQSSNGGWGAFDIDNDKQI LNDIPFADHGALLDPPTADVSARCISLLAELGHPEDRPVIERGIKYLRKEQEEDGSWFGRWGTN YIYGAWSVLCAFNASGVPHDDPSVLKCVNFLKSVQREDGGWGESCETYEGSAHGVYTESLPS QTAWAVLGLMASGRRTDPAVKRGIVWLIQHQQDNGEWAEEPFNAVGFPRMFYLHYLGYKQF FPLLALARYRHMEKSGTNNVSFAF >seq_ID 11 MLPYNQDHHFGKVAENATMPPTLDEAIERSQDFLLSLQYPEGYWWAELEANVTLTAQTIMLYKI LGIDHKYPIHKMKTYILRTQRAHGGWEIFYGDGGCLSTTIGAYMALRILGVPKTDPVLQKALKLIH SKGGVTKSRMFTKICLALLGCYDWKGIPSLPPWLVLLPSWFPFSLYDTASWVRGCVVPLTIIFD KKPVYKLNPLLCLDELYSEGKGKARVHLSFIPGDWTSNFFVGLDHVFKYMENLGVVPFRQWGI KEAERWTLERHEDSGDFHGIYPPMFYSIVSYSLLGYEITDPVVHRALESMRGFTVEREDECVV QSCISPMWDTAFVIRSLAESGLQPDHPALQKAGEWLLQKQATQHGNWFYKKRTGRAGGWAF QFFNRWYPDVDDSAAVSMALNAIKLQDDDVKKGAIKRCAEWISVMQCKDGGWAAYDCDNDR EWLNCTPFGDLKAMIDPNTVDVTARVLEMVGRVKEAGDASAILPPRAIARGLAYLRREQETEG CWYGRWGVNYIYGTSGALMALALVAPSTHKEEIERGARWLVEVQNKRGTKGANGYSHTNGA REGGVAMNGNCKNMGAPEDGGWGETCFSYNDITLKGRNEVSTVSQTAWALQGLLAAGDALG KYEVESIEHGVQYLLSTQRKDGSWCEKHFTGGGFPRFFYIRYHLYAGHFPLSALARYRDRVRA GKMAK >seq_ID 214 MDATAPLRDPGAPSAENCSVDRRELDDVIGESCRWLGERQNQDGHWVFELEADATIPAEYILL NHFLDEIDDAREARIASYLRAIQGKHGGWPLFHDGDFDMSATVKAYYALKLTGDGVDEPHMVR ARQAILEHGGAERTNVFTRFTLAMFDQVPWRACPVTPVEALLLPRFAPFHWSKVSYWSRTVM TPLMILYSRRARAVNPRGIGVRELFRRDPEVIRDWLKNPTGHWIGDALIQIDKVLRVIEPAIHWAF RDRAEKWALDFIEERLNGRDGLGGIYPAIANTLMAYHTLGYAKDHPGYRIAREAVDGLCTPHAK GEYVQPCLSPVWDTCLASHAIQEAGQSAGDRAVDQSNAWLRERQVLDVVGDWKSNRGHLRP GGWAFQYNNPHYPDVDDTAVVVMALARSKEDEANREAIARAEEWIIGMQSSNGGWGAFDAE NEHDFLNHVPFADHGALLDPPTVDVSARCLGMLAQLGRPKTDPVVARGLDYLWREQEADGS WFGRWGTNYIYGTWSALNAFNAVEWDMTDPRICKAVDWLKSRQRDDGGWGEDCATYWKER RSVSKASTPSQTAWAVLGLMAAGEVDSPEVERGIRYLLEAPRDGGKWEEELYNAVGFPRIFYL RYHGYSAYFPLWALARYRNLTSGNCKRTIHGM >seq_ID 73 MPEEAILTETHPLDATTIETAITRARKALLGEQRADGHFVFELEADVSIPCEYILFYHFIGRPAPAE LEAKIGHYLRARQSAEHDGWPLFQDGAFNISSSVKAYFALKAIGDTPDMPHMQRARTAILAHG GAAAANVFTRSLLALFGLIPWHGIPVMPIEIMHLPEWFPFHIAKISYWGRTVLVPMMVVHALKPK PANTCTIRIDELFVIPPDQVRHWPGSPGKRFPWTAIFAGIDKVLQIAERYFPRRSRQSAIDKAVA FVTKRLNGEDGLGAIYPAMAYSALMYLSIGRSLSDPHIQLVLKAIDKLVVVKDHEAYVQPCVSPV WDTALASHALMEAGDGDKPILDSLKKGLAWLKPLQVTDIAGDWAWKKPDVKPGGWAFQYGN AYYPDLDDTAVVVMAMDRARDRWPEIDEDNFRPSIARAREWIVGLQSENGGFGAFDADNDRD YLNAIPFADHGALLDPPTADVTARCISMLTQLGEKPENSETLRRAIAYLFAEQEKDGSWFGRWG LNYIYGTWSVLCSLNAAGIAHDAPEVRRAVAWLRTIQNEDGGWGEDAESYALDYAGYQQAPS TSSQTAWAVLGLMAAGEKDDPAVARGIAYLTRTQGEDGFWTEKRFTATGFPRVFYLRYHGYS KFFPLWAMARYRNLHNGNHASVLTGM >seq_ID 103 MNDMTEMHTLDATAVPAAPAAADAPAPSAATTGLDAAVARATDALLAAQNADGHWVYELEAD STIPAEYVLLVHYLGEEPNAELEQKIARYLRRIQQPDGGWPLFTDGAPNISASVKAYFALKVIGD DENAEHMQRARRAIHAMGGAEMSNVFTRIQLALYGVVPWYAVPMMPVEIILLPQWFPFHLSKV SYWARTVIVPLLVLNAKRPVAKNPRGVRIDELFKSAPVNTGLLPKQPHQHAGWFAFFRAVDGV LRLADGLFPRYTRERAIRQAAAFVDERLNGEDGLGAIYPAMANAVMMYAALGYPEDHPNRAIA RQSIEKLLVVGEEEAYCQPCLSPVWDTSLAAHALLETGDERAREAAVRGLDWLVPRQILDVRG DWISRRPHVRPGGWAFQYANAHYPDVDDTAVVVMAMDRVAKHDQTDAYRESIARAREWVVG MQSSDGGWGAFEPENTQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQLGETSASSEPARR ALDYMLKEQEPDGSWYGRWGMNYIYGTWTALCSLNAAGLGHDDPRVKRAAQWLLSIQNPDG GWGEDGDSYKLDYRGYERAPSTSSQTAWALLGLMAAGEVDNPAVARGIGHLLGTQREHGLW DETRFTATGFPRVFYLRYHGYRKFFPLWALARYRNLKRAGAARVTVGM >seq_ID 95 MNDMTEMHTLDAAAAPAADAPAVTAVTAGLDAAVARATDALLAAQNADGHWVYELEADSTIPA EYVLLVHYLGEEPNAELEQKIARYLRRIQQPDGGWPLFTDGAPNVSASVKAYFALKVIGDDENA EHMQRARRAIHAMGGAETSNVFTRIQLALYGVVPWYAVPMMPVEVMLLPQWFPFHLSKVSYW ARTVIVPLLVLNAKRPVAKNPRGVRIDELFKSAPVNTGLLPKQPHQSTGWFAFFRAVDGVLRLV DGLFPRYTRERAIRQAVAFVDERLNGEDGLGAIYPAMANAVMMYAALGYPEDHPNRAIARQSI EKLLVVGEEEAYCQPCLSPVWDTSLAAHALLETGDERARDAAVRGLDWLIPRQILDVRGDWIS RRPHVRPGGWAFQYANPHYPDVDDTAVVVMAMDRVAKLDQSDAYREQIARAREWVVGMQS SDGGWGAFEPENTQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQLGETNASSEPARRAFD YMLKEQEPDGSWYGRWGMNYIYGTWTALCALNAAGLGHDDPRVKRAAQWLLSIQNQDGGW GEDGESYKLDYRGYERAPSSSSQTAWALLGLMAAGEVDNPVVARGIDYLLGAQCEHGLWDET RFTATGFPRVFYLRYHGYRKFFPLWALARYRNLKRANTTRVTVGM >seq_ID 106 MNDLTDMPTLAADSAAADLDAAVARATDALLAAQQADGHWVYELEADSTIPAEYILLVHYLGET PNLELEQKIGRYLRRIQQPDGGWPLFTDGAPNISASVKAYFALKVIGDDENAEHMQRARRAIHA MGGAEMSNVFTRIQLALYGAIPWRAVPMMPVEIMLLPQWFPFHLSKVSYWARTVIVPLLVLNAK RPIAKNPRGVRIDELFIDPPVNAGLLPRQGHQSAGWFAFFRVVDHALRAVDGLEPSYTRERAIR QAVAFVDERLNGEDGLGAIYPAMANAVMMYDALGYPEDHPNRAIARRSVEKLLVVHDDEAYC QPCLSPVWDTSLAAHALLETGDPRAEDAVVRGLEWLRPLQILDVRGDWISRRPNVRPGGWAF QYANPHYPDVDDTAVVVMAMDRVEKLRHSDAYREAISRAREWVVGMQSSDGGWGAFEPEN TQYYLNNIPFSDHGALLDPPTADVSGRCLSMLSQLGETAANSEAARRSLDYMLKEQEPDGSW YGRWGMNYVYGTWTALCSLNAAGLGPDDPRVKRGAQWLLSVQNKDGGWGEDGDSYKLDY RGYEQAPSTSSQTAWALLGLMAAGEVNHPAVARGIDYLIAEQKEHGLWDETRFTATGFPRVFY LRYHGYRKFFPLWALARYRNLKRANATRVTVGM >seq_ID 87 MNDLTEMATLSAGAVPAGVDAAVARATDALLAAQQADGHWVYELEADSTIPAEWLLVHYLGE TPNLELEQKIGKYLRRIQQADGGWPLFTDGAPNISASVKAYFALKVIGDDENAEHMQRARRAIH AMGGAEMSNVFTRIQLALYGAIPWRAVPMMPVEIMLLPQWFPFHLSKVSYWARTVIVPLLVLNA KRPLAKNPRGVRIDELFIDPPVNAGLLPRQGHQSPGWFAFFRVVDHALRAVDGLFPSYTRERAI RQAVSFVDERLNGEDGLGAIYPAMANSVMMYAALGYAEDHPNRAIARKSVEKLLVVHDDEAYC QPCLSPVWDTSLAAHALLETGDARAQEAVLRGLEWLRPLQILDVRGDWISRRPNVRPGGWAF QYANAHYPDVDDTAVVVMAMDRAQKLTQSDTYRESMARAREWVVGMQSSDGGWGAFEPEN TQYYLNNIPFSDHGALLDPPTADVSGRCLSMLSQLGETPLNSEPARRALDYMLKEQEPDGSWY GRWGMNYVYGTWTALCSLNAAGLTPDDPRMKRGAQWLLSIQNKDGGWGEDGDSYKLNYRG YEQAPSTASQTAWALLGLMAAGEVNNPAVARGVDYLVAQQNEEGLWDETRFTATGFPRVFYL RYHGYRKFFPLWALARYRNLKRANATRVTVGM >seq_ID 107 MNDLTDMANLSAGTVPAGLDASVARATDALLAAQNADGHWVYELEADSTIPAEYVLLVHFLGE TPNLELEQKIGRYLRRIQQADGGWPLFTDGAPNVSASVKAYFALKVIGDDENAEHMQRARRAI HAMGGAEMSNVFTRIQLALFGAIPWRAVPMMPVEIMLLPQWFPFHLSKVSYWARTVIVPLLVLN AKRPLAKNPRGVRIGELFIDPPVNAGLLPRQGHQSPGWFAFFRVVDHALRAADGLFPSYTRER AIRQAVSFVDERLNGEDGLGAIYPAMANAVMMYDVLGYPEDHPNRAIARKSIEKLLVVHDDEAY CQPCLSPVWDTSLVAHALLETGDARAEQAVLRGLDWLRPLQILDVRGDWISRRPNVRPGGWA FQYANAHYPDVDDTAVVVMAMDRAQKLQNTDTYRESIARAREWVVGMQSSDGGWGAFEPE NTQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQLGESALSSEPARRALDYMLKEQEPDGS WYGRWGMNYVYGTWTALCSLNAAGLGPEDPRVKRAAQWLLSIQNKDGGWGEDGDSYKLNY RGFEPAPSTASQTAWALLGLMAAGEVNHPAVERGIGYLIAQQNDEGLWDETRFTATGFPRVFY LRYHGYRKFFPLWALARYRNLKRANATRVTVGI >seq_ID 212 MESGNNKQPAAAIGALDASIESATNALLGYRQPDGHWVFELEADCTIPAEYVLLRHYLGEPVDA ALEAKIANYLRRVQGAHGGWPLVHDGGFDMSASVKGYFALKMIGDDIDAPHMAKAREAIRSRG GAIHSNVFTRFLLSMFGITTWRSVPVLPVEIMLLPMWSPFHLNKISYWARTTIVPLMVLAALKPR AVNRLDIGLDELFLQDPKSIKMPAKAPHQSWALFKLFAGIDAVLRTIEPLFPKRLRDHAIKLAVDF VEERLNGEDGLGAIYPPMANTVMMYKVLGFPEDHPPRAITRRGIDKLLVIGEDEAYCQPCVSPV WDTALTCHALLEVGGEAAVPPAKRGMDWLLPKQVLDLKGDWAVKRPNLRPGGWAFQYNNAH YPDLDDTAVVVMAMDRSRRATGSREYDEAIARAREWIEGMQSDDGGWAAFDVNNLEYYLNNI PFSDHGAMLDPPTEDVTARCVSMLSQLGETAASSKAVADGVEYLRRTQLPDGSWYGRWGLN YIYGTWSVLCALNAAGVDHQDPVIRKAVTWLASVQNPDGGWGEGAESYRLNYTRYEQAPTTA SQTSWALLGLMAAGEVDSPVVARGVEYLKSTQTGKGLWDEQRYTATGFPRVFYLRYHGYAKF FPLWALARYRNLRSTNSKVVGVGM >seq_ID 101 MNDLTEMATLSAGAVPAGVDTAVARATDALLAAQNADGHWVYELEADSTIPAEYVLLVHYLGE TPNLELEQKIGKYLRRIQQADGGWPLFTDGAPNISASVKAYFALKVIGDDENAEHMQRARRAIH AMGGAEMSNVFTRIQLALYGAIPWRAVPMMPVEIMLLPQWFPFHLSKVSYWARTVIVPLLVLNA KRPLAKNPRGVRIDELFIDPPVNAGLLPRQGHQSAGWFAFFRVVDHALRAVDGLFPNYTRERAI RQAVSFVDERLNGEDGLGAIYPAMANSVMMYDVLGYAEDHPNRAIARKSIEKLLVVQEDEAYC QPCLSPVWDTSLAANALLETRDARAEDAAIRGLEWLRPLQILDVRGDWISRRPHVRPGGWAF QYANAHYPDVDDTAVVAVAMERAQQLKQNDAYRDSIARAREWVVGMQSSDGGWGAFEPEN TQYYLNNIPFSDHGALLDPPTADVSGRCLSMLSQLGETPLNSEPARRALDYMLKEQEPDGSWY GRWGMNYVYGTWTALCSLNAAGLTPDDPRVKRGAQWLLSIQNKDGGWGEDGDSYKLNYRG FEQAPSTASQTAWALLGLMAAGEVNNPAVARGIDYLIAEQNAEGLWDETRFTATGFPRVFYLR YHGYRKFFPLWALARYRNLKRDNTTRVTVGL >seq_ID 112 MSAPSHVGNTLEHAAELATRKAMAYLTCLQERDGHWCAELTADTTLESDYILFQLWLYPPQDG KWEPETRPLIRKAVNSILERQLPDGGFNICVGGPSEVSASVKAYVAMKLAGLPPEDDRMARLR ERILALGGIQAANSYVKVNLSLFDLYPREFSPSIPPEVALLPFDLLYQMSAWTRAIVISLGIVHAAN PRRPAPAGFNLQELWLPGVSPEFRRDPSFFTWHNTFLTVDKALKLWERYGSKAVRRRAVEKA KTWMIERLHHSDGLGAIYPPMMYSVMALDVLGYAKDDPLRVEALRHFNNLMVDDGDRFFFQP CFSPVWDTAIGAYALVQADPSHEAIAPAADWLIAKEVRRKGDWSVKRPNTEPSGWAFEYSNE YYPDIDDTAMVMLALGETRASNTEAQAAACKRGLAWLLAMQSSDGGWAAFDADNNWEFLSQ VPFADHNAMLDPTCADITGRVLEALASQGLDRNHKAVRRGAEWLIRHQENDGSWYGRWGVA YIYGTCFALRGLAASGENDREAHILRAGEWLRSIQNADGGWGESCKSYDNRIFTGGPSTPSQT AWAILGLIAGGDANSLSVQHGIEYLLETQRSDGSWDEQFATGTGFPRVFYLNYHMYKDYFPLL ALASFVKARAGSNG >seq_ID 83 MNDLTEMATLSAGTVPAGLDAAVASATDALLAAQNADGHWVYELEADSTIPAEYVLLVHYLGE TPNLELEQKIGRYLRRVQQADGGWPLFTDGAPNISASVKAYFALKVIGDDENAEHMQRARRAI HAMGGAEMSNVFTRIQLALYGAIPWRAVPMMPVEIMLLPQWFPFHLSKVSYWARTVIVPLLVL NAKRPIAKNPRGVRIDELFVDPPVNAGLLPRQGHQSPGWFAFFRVVDHVLRAADGLFPSYTRE RAIRQAVSFVDERLNGEDGLGAIYPAMANAVMMYDVLGYAEDHPNRAIARKSIEKLLVVHEDEA YCQPCLSPVWDTSLAAHALLETGDARAEEAVIRGLEWLRPLQILDVRGDWISRRPHVRPGGW AFQYANAHYPDVDDTAVVAVAMDRVQKLKHNDTFRDSIALAREWVVGMQSSDGGWGAFEPE NTQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQLGETPLNSEPARRALDYMLKEQEPDGS WYGRWGMNYVYGTWTALCALNAAGLTPDDPRVKRGAQWLLSIQNKDGGWGEDGDSYKLNY RGFEQAPSTASQTAWALLGLMAAGEVNNPAVARGVEYLIAEQKEHGLWDETRFTATGFPRVF YLRYHGYRKFFPLWALARYRNLKRDNATHVTFGL >seq_ID 175 MLQTEAITTEGLRFRSLAPDDPLLPRVKQALKLSGQHSREEMHSDGHWCGEVKTNATTSAEH VLLCQALDINLDADREAFISWFRCTQGADGGWSTAPDQAGDISVTVEAYLALKILGLSEDDAAM RSARDFAIAAGGVARVRIFTRIYLAMFGLFPWAAVPELPPELILLPSRVPVSIYHWSAWARATVV PLLIISHHRPIYALPGGKATCSDYLDELWCDPRNKMVPYNHDKPTAWRSDPFALIFTLADSILHR LDGLRSFNPLRRFALRKCVDWILEHQEDMGDIGDIMPPLHGAMLALRLEGYPLHSDPIHRGLEA IERFAYRDQQGKRIQTTVSAFWDTSLMLVALGDAGMASSPWLTRSLGWLQQHQRLGNYGDW KVNNPGLKAGGFSFGYFNTWYPDVDDTASAVLAIIRQDERLVCSASVLDALNWLLGMQNTDG GWGAFDRDNNKLFLNKIPFSDMEAFCDPSTPDVTGHVLEAFGIFLAVSARQQSPTKADVLTDRI VSASRRAICYLSDTHVSSGGWYGRWGCNYIYGTSAVLCALAYFGSKSDTLSGVRSVKDAVNQ AIRWLETVQNQDGGWGETVNSYKDPSRAGSGPSTASQTAWAIMALLPYLPPSTEVIQRGVEYL LRTQTKTASQGATWHEKAYTGTGFPKYFYMGYSFYCHYFPMMALGRYAYPCPEWHENWRPK KE >seq_ID 88 MNDLTDMATLSAGAAPAADLDAAVARATDALLAAQNADGHWVYELEADSTIPAEYVLLVHYLG ETPNLELERKIGRYLRRIQQADGGWPLFTDGAPNVSASVKAYFALKVIGDDENAEHMQRARRAI HAMGGAEMSNVFTRIQLALYGAIPWRAVPMMPVEIMLLPQWFPFHLSKVSYWARTVIVPLLVL NAKRPLAKNPRGVRIDELFIDPPVNAGLLPRQGHQSAGWFAFFRVVDHVLRAVDGLFPKYTRE RAIRQAVSFVDERLNGEDGLGAIYPAMANAVMMYDVLGYAEDHPNRAIARKSIEKLLVVHDDEA YCQPCLSPVWDTSLAAHALLETGDPRAEDAALRGLEWLRPLQILDVRGDWISRRPNVRPGGW AFQYANAHYPDVDDTAVVAMAMDRAQKLRQSDTYRESIARAREWVVGMQSSDGGWGAFEP ENTQYYLNNIPFSDHGALLDPPTADVSGRCLSMLSQLGESALTSEPARRALDYMLKEQEPDGS WYGRWGMNYVYGTWTALCALNAAGLGPDDPRVKRAAQWLLSIQNKDGGWGEDGDSYKLNY RGYEQAPSTASQTAWALLGLMAAGEVNNPAVARGIDYLLAEQKEHGLWDEVRFTATGFPRVF YLRYHGYRKFFPLWALARYRNLKRANATRVTVGM >seq_ID 92 MNDMTEMHTLDATAAPAGLDAAVARATDALLAAQQADGHWVYELEADSTIPAEYVLLVHYLGE APNVELEQKIARYLRRIQQPDGGWPLFTDGAPNISASVKAYFALKVIGDDENAEHMQRARRAIH AMGGAEMSNVFTRIQLALYGVVPWYAVPMMPVEIMLLPQWFPFHLSKVSYWARTVIVPLLVLN AKRPVAKNPRGVRIDELFKGAPVSTGLLPKQPHQSAGWFAFFRAVDGVLRLVDGLFPRYTRER AIRQAVAFVDERLNGEDGLGAIYPAMANAVMMYAALGYPEDHPNRAIARRSIEKLLVVGEQEAY CQPCLSPVWDTSLAAHALLETGDARAREAAVRGLDWLVPRQILDVRGDWISRRPHVRPGGWA FQYANAHYPDVDDTAVVAMAMDRVAKLDRTDAYRESIARAREWVVGMQSSDGGWGAFEPEN TQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQFGETSASSEPARRALDYMLKEQEPDGSW YGRWGMNYIYGTWTALCSLNAAGLGHDDPRVKRAAQWLLSIQNADGGWGEDGDSYKLDYR GYERAPSTSSQTAWALLGLMAAGEVDNPAVARGVDYLLGTQREHGLWDETRFTATGFPRVFY LRYHGYRKFFPLWALARYRNLKRANAMRVTVGM >seq_ID 206 MTRKTIPASELDAAIVRARDALLDRQHPDGHWCFELECDATITAEYILMMHFVDEIDTALQARM AKYLRAVQRLDGHGAWDLYFGGDLDISCSVKAYFALKAAGDPPDAPHMVRAREAILARGGAA KSNVFTRILLATFGEIPWRGTPFMPVEFVLFPRWAPIHMDKVAYWARTTMVPLLVLCSIRAAAK NPLGVHVQELFVTPPELEREYFPRKRGLQQAFLVADRVVRHLEPLIPRALRRRAIQRAVEWSEA RMNGEDGFGGIFPPMVYSYEMMVLLDYPEDHPLRVECKAALKKLVVHRDDGSSYCQPCLSPV WDTAWSVMALEQAPSDARTETAIARAYDWLTDRQVLDLRGDWENNAAPSTPPGGWAFQYEN PYYPDIDDSAVVLAMLHARGKRTGQPGRYEMPVARCLDWIIGLQSRNGGFGAFDANCDRDFL NAIPFADHGALLDPPTEDVSGRVLLALGITERPQDATARERCIQYLRDTQQPDGSWWGRWGT NYIYGTWSVLAGLGLAGVDRKLPMVRNGLQWLRGKQNADGGWGETNDSYARPELAGKHED GSMAEQTAWAMLGQMAVGEGDADSVHRGAAYLLDAQNEDGFWMHPYHNAPGFPRIFHLKY HGYTAYFPLWALGRYRRLAAARASAMQTAKAESAESMTAH >seq_ID 96 MNDLSMTQTLGEVLPQTLIDDHAPVAAALATGAAPVDALDAAVTRATEAILAVQKDDGHWVYE LEADATIPAEYVLLVHFLGETPNLELEQKIARYLRRIQLPNGGWPLFTDGAMDVSASVKAYFALK MIGDPEDAAHMVRARECILANGGAEAANVFTRILLALFGVVTWYAVPMMPVEIMLLPKWFPFHL SKVSYWARTVIVPLLVLNAKRPVARNPRGVRIDELFRGAPVTTGLLPRSGHQSKSWFAFFRAV DGVLRVTDGLFPKASRERAIKAAVSFVDERLNGVDGLGAIFPAMANSVMMYDVLGYPADHPNR AIARESIEKLLVVHEDEAYCQPCLSPVWDTSLAAHALLETGDARAEEAAERGLAWLRPLQILDV RGDWISRRPDVRPGGWAFQYNNAHYPDVDDTAVVAMAMHRSAAVTNSNVDANAIARAREWV VGMQSSDGGWGAFEPENTQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQLGEMPATSEPA RRAYDYLLKEQEDDGSWYGRWGMNYIYGTWTALCALNAAGISLEDARIKRAAQWLVSIQNAD GGWGEDGTSYKLDYRGYEKAPSIPSQTAWALLGLMAAGYVDHPAVARGIDYLQREQRDHGL WDEERFSATGFPRVFYLRYHGYRKYFPLWALARYRNLKRTGEKRVTVGM >seq_ID 104 MNDMTEMHTLDATAAPAAPTVATGLDAAVARATDALLAAQNADGHWVYELEADSTIPAEYVLL VHYLGEAPNVELERKIARYLRRIQLPDGGWPLFTDGAPNISASVKAYFALKVIGDDENAEHMQR ARRAIHAMGGAEMSNVFTRIQLALYGVVPWYAVPMMPVEIMLLPQWFPFHLSKVSYWARTVIV PLLVLNAKRPVAKNPRGVRIDELFKSAPVNTGLLPKQPHQSAGWFAFFRAVDGVLRLTDGLFP RYTRERAIRQAVAFVDERLNGEDGLGAIYPAMANAVMMYAALGYPEDHPNRAIARQSIEKLLVV GEDEAYCQPCLSPVWDTSLAAHALLETGDERAREAAVRGLDWLVPRQILDVRGDWISRRPHV RPGGWAFQYANAHYPDVDDTAVVAMAMDRVAKLDRTDAYRESIARAREWVVGMQSSDGGW GAFEPENTQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQFGETSASSEPARRALDYMLKEQ EPDGSWYGRWGMNYIYGTWTALCSLNAAGLGHDDPRVKRAAQWLLSIQNPDGGWGEDGDS YKLDYRGYERAPSTSSQTAWALLGLMAAGEVDHPAVARGIDHLLGTQREHGLWDETRFTATG FPRVFYLRYHGYRKFFPLWALARYRNLKRANATRVTVGM >seq_ID 27 MAHQETMASETSISLHTLACDATKLAGTYALRQVREDGHWYGEMKSNATITAEYVFLAQALGF SIEEDRDDLIKYFLSEQNTDGSWSLAYDFPGDVSVTAEAYFALCLLGLDRSHPAMASAREFTLS KGGIAKVRVFTRMFFACFGLFPWSAVPELPAELILLPAAAPMSIYQLASWARATVVPMLVIRHH RPIYALPNGRSSSNEYLDELWVDPTDKMVPYSPSLWSLWNDDLTAFGFTLADNILKALGGLRW FPSRKIALRHCVAWILERQEPEGDIGGIFPPLHAALFALALEGYGLESSPVRRGIDALQNTYAWR DSTGLRIQGCISPILDTILMTIGLIDSSLPAESPLVARSSRYLKAHQQLGNEGDWRVYNGNVPSG GFNFEYFNSWYPDIDDTAAAILAMVKQDPNLLDLGPILSAVQWILGLQNDDGGWAAFDRENNY LFLNKIPFSDMDSFCDPSTADVTGRVIECFGLNGKNPIPRFFIDDMSSATERAIDFLSTEQEADG SWYGRWGSNYIYGTSAVLCGLVYHLEGWDDTYPVMEKRHKVDTHAALDWLKRHQNPDGGW GERLESYYEPRLAGNGPSTASQTAWALMGLLAYLAPTDESITRGIQYLSRTQIKEGELAGSWKE DHYTGTGFPNHFYLCYTLYSQYFPMMALGRYTSLSGYRPLENLESTVEDHKGNSSDC >seq_ID 28 MMTLREEGHKEGITPGKEQLTSDIEHSLKLATEYALSSIRSDGHWCGELRSNVTITAEYIFLRHA LGLDLRTDNAAYCRYILSQQNCDGSWGLAPEYPGDVSTTTEAYLALKLLGTSPDMPAMQQAR AFVRKAGGAEKVRVFTRIFLATFGLFPWDAVPQLPVELILLPSSCPINMYTLASWARGTIAPLLII CHHQPVYALPEDYLDELWLDPTDKNVPYGSSLRDLLSRGDITGLAFSVVDNLLYYLNGLRSVPL LRSYARRKCIQWILERQEPTGDWAGIFPPMHASIYAFVLEGYELNDPPVRLGIQALENFAWEDE KGKRIQACVSPVWDTALMSIGLCDAMSPDKQILQQAITWIRNRQLLKPCGDWRIYRSKLAPGGF SFEYENSHYPDVDDTAAIILAQLKQDPQSVASDSVIAAATWILGMQNPDGGWAAFDVENDKLFL NKIPFSDMDSLCDTSCADITGRILEAFGLMMKRELKRPVLSPMLRHACIRGITYLASTQESNGA WFGRWGCNYIYGTCHALGLVAPALQWLKSKQNDDGGWGEPLLSYRTPGTQLQQQSTPSQTA WALMGLLAHLPLTDPAIERGIRWLVCSQQPEKGNGASWPEAVYTGTGFPNHFYLGYDYYRHY FPMMALGRYLQASQAQA >seq_ID 94 MNDLTDMATLSAGTVPAELDAAVARATDALLAAQNADGHWVYELEADSTIPAEYVLLVHYLGE TPNLELEQKIGRYLRRIQQADGGWPLFTDGAPNISASVKAYFALKVIGDDENAEHMQRARRAIH AMGGAEMSNVFTRIQLALYGAIPWRAVPMMPVEIMLLPQWFPFHLSKVSYWARTVIVPLLVLNA KRPLAKNPRGVRIDELFIDPPVNAGLLPRQGHQSAGWFAFFRAVDHVLRAVDGLFPAYTRERAI RQAVAFVDERLNGEDGLGAIYPAMANAVMMYDVLGYAEDHPNRAIARKSIEKLLVVHEDEAYC QPCLSPVWDTSLAAHALLETRDPRAEQAAVRGLDWLRPLQILDVRGDWISRRPHVRPGGWAF QYANPHYPDVDDTAVVAMAMDRAQKLNQSDTYRESIARAREWVVGMQSSDGGWGAFEPEN TQYYLNNIPFSDHGALLDPPTADVSGRCLSMLSQLGETALNSDAARRALDYMLKEQEPDGSW YGRWGMNYVYGTWTALCALNAAGLGPDDARVKRAAQWLLSIQNKDGGWGEDGDSYKLNYR GYEPAPSTASQTAWALLGLMAAGEVNNPAVKRGIDYLIAEQKEHGLWDEARFTATGFPRVFYL RYHGYRKFFPLWALARYRNLKRDNTTRVTVGI >seq_ID 30 MERSSLLVPASIDSHSRESETTGLDQAIVRARAALLGRQGADGHWCFELESDCTITAEYILMMH FTDEIDEDLQERMARYLRATQVQETHGGWPQYVGGAIDLSCTVKAYYALKAAGDSPEAPHMR RAREAVLALGGAAKSNVFTRILLAMFEQVPWRAVPYLPVEIMLLPRWAPIHIEKMSYWARTTLV PLTILCSLKARAANPKRVDIRELFVTAPEQERHYFLRGGLLNRIFLGLDKFARTLDRWMPKSLRQ HAIRKAEAWFLPRMNGEDGLGAIFPPMVNCYEAMILLGYPKDHPARKTCLRSIQKLIVHRDDGS AYCQPCVSPVWDTAWSAMALIHSGDDTATQTAIARAGDWLVQRQELDCRGDWEAQAPQAAP GGWAFQYANGYYPDIDDTALVAALLHISDRRRGQPGQHAFNIDRAVDWMLALQSRNGGFAAF DADNTHYYLNAIPFADHGALLDPPTEDVSGRVAACLGILKRDQDRDGLRRCIDYLRTTQQPDG SWWGRWGSNYIYGTWSALSGLALAGEDLRQPYLRKSVDWLRTRQHPDGGWGETNDSYIDP HLAGTNAGISTPHSTAWAVLAQLAMGEVESDSVRRGIAFLLACQQTDGLWSHPSHNAPGFPR VYYLKYHGYAAYFPLYALARYRHLLNRSREQR >seq_ID 98 MNDMTEMHTLDATAAPAGLDAAVARATDALLAAQQADGHWVYELEADSTIPAEYVLLVHYLGE APNVELEQKIARYLRRIQQPDGGWPLFTDGAPNISASVKAYFALKVIGDDENAEHMQRARRAIH AMGGAEMSNVFTRIQLALYGVVPWYAVPMMPVEIMLLPQWFPFHLSKVSYWARTVIVPLLVLN AKRPVAKNPRGVRIDELFKGAPVSTGLLPKQPHQSAGWFAFFRAVDGVLRLVDGLFPRYTRER AIRQAVAFVDERLNGEDGLGAIYPAMANAVMMYAALGYPEDHPNRAIARRSIEKLLVVGEQEAY CQPCLSPVWDTSLAAHALLETGDARAREAAVRGLDWLVPRQILDVRGDWISRRPHVRPGGWA FQYANAHYPDVDDTAVVAMAMDRVAKLDRTDAYRESIARAREWVVGMQSSDGGWGAFEPEN TQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQFGETSASSEPARRALDYMLKEQEPDGSW YGRWGMNYIYGTWTALCSLNAAGLGHDDPRVKRAAQWLLSIQNADGGWGEDGDSYKLDYR GYERAPSTSSQTAWALLGLMAAGAVDNPAVARGVDYLLGTQREHSLWDETRFTATGFPRVFY LRYHGYRKFFPLWALARYRNLKRANATRVTVGM >seq_ID 187 MTSDTASAAALDPRRLATSITRASRALHDVQQPDSHWVFELEADVTIPAEYVMMRHYFAEPVD AEIEAKIAKYLRRMQNDNGGWSLFYGHEFDMSASVKAYYALKMIGDSPDAPHMKKAREAMLA RGGASRANVFTRIMLALFGQVSWKAVPMMPVEIMLLPRWFPFHLTKVSYWARTVIVPLLVLMT LKPRAKNPRGIGVRELFLEDPQTVGPTPKAAHQSQLWFTSFDIIDRVLRITDPFFPKGMRKRAIA KAEAFVTERLNGVDGLGAIFPAMVNSIMMYDVLGYPPNDPNRALARESVERLLVIKDDEAYCQP CVSPVWDTALAAHSMLESGEAADIEAAKAGLDWLLPRQVLDLKGDWADKRPDVRPGGWAFQ YNNAHYPDLDDTAVVVMAMDRVRRLDGTTKYDEAIARATEWILGLQSENGGWAAFDADNLEY YLNNIPFADHGALLDPPTEDVTARCLSMLAQLGDTLETSEPMRRGVEYLRKTQLPDGSWFGR WGINYVYGTWSVLCALNAVGVPHDDPMIAKAADWLESIQNEDGGWGEDGNSYKLNYKGYER AATTASQTAWATLALMAAGRVDRDATQRGIDNLVQSQEADGFWGEPYYTGGGFPRVFYLRY HGYSKFFPLWAMARYRNLRSSNSRFVGAGM >seq_ID 207 MNKHSGNRTAIDPAALEMSIASATEALLAYRHADGHWAFELEADSTIPSEYILLRHYLAEPIDVVL EAKIGNYLRRTQGAHGGWPLVHDGPFDMSASVKSYFALKMIGDSVDAAHMVKAREAIRARGG AANSNVLTRFLLALYGVVSWRAVPVLPIEIVLLPIWSPFHLYKISYWARTTIVPLMVLAVLKPRAK NPKGVGIEELFLQDTKSVGMNPKAPHQSWGWFLLFRGIDGILRVIEPHLPKKLRERAIASALAFT EERLNGEDGMGAIYPSMANIVMMYDALGKDDHFPPRAIARRAIDKLLVIGEEEAYCQPCLSPVW DTALTCHALQEVGGANAVAKAKQGLDWLKPRQVLDVKGDWAVKAPNIRPGGWPFQYNNAHY PDLDDTAVVVMAMDRAQRHAGSKEYATAIARGREWIEGMQSRDGGWAAFDVNNLEYYLNNL PFADHGALLDPPTEDVTARCVSMLAQVGEFTQRSKAVAEGIAYLRRTQHAEGSWYGRWGLNY IYGTWSVLCALNAAGIDHQDPMIRKAVEWLVSIQSWDGGWGEDAISYRLDYSGYEQAPSTSSQ TAWALLGLMAAGEVEHPAVARGVNYLKNAQTENGLWDEQRYTATGFPRVFYLRYHGYSKFFP LWALARYRNLRSTNV >seq_ID 29 MTTGHRQFDDGLSERERLIHEAGLTLQRSMDYAYNVVRSDGHWCGEMSSNVTITAEYIFLRQA LGLDLKTDGAAYCRHILSQQNSDGSWGLAPEYPGDVSTTTEAYLALKMLGLSTDAPAMQQAK AFVLNAGGVAKVRVFTRIFLATFGLFPWKAVPQLPVELILLPSACPINIYKFASWARGTIAPLLIIC HHQPVYALPNGVFAENEYLDELWQDSTNKSEPYSPSIWELLSQGDITGLTFSLLDKLLYQLNGL RSIPLLRSYALKQCMKWILERQEPTGDWAGIFPPMHASVYAFVLEGYKLEDPPVRLGIEALENF AWEDAKGKRVQPCVSPVWDTTLMSIALSDAATPNHQIVDRAIQWIRDRQLLEPRGDWRVYRP RLAPGGFSFEYTNSHYPDIDDSAAIILAQVKHDPISANSSSVIAAATWILGMQNPDGGWAAFDV ENDKLFLNKIPFSDMDSLCDTSCADITGRILEAFGLLIRRVPDKDSSQLFQLLPAIRAACRRGIRY LASTQEANGAWFGRWGCNYIYGTSHALCGLAYFLQEDQQVPAMVQPALQWLKSQQNDDGG WGESLLSYQSPERKEQRSTASQTAWALMGLLAHLPHTDIVIERGIRWLVSSQRPVETLGSTWP EPVYTGTGFPNHFYLGYDYYRHYFPMMALGRYLRGVQG >seq_ID 25 MLQTEAITTEGLRVRSLSPDDPLLPRIKQAIKLSGQHSRGEMHSDGHWCGEVKTNATTSAEHV LLCQALGINLDADREAFISWFRCTQGADGGWSTAPDQAGDISVTVEAYLALKILGLSEDDAAMR RARDFAIAAGGVAKVRIFTRIYLALFGLFPWAAVPELPPELILLPSRVPVSIYHWSAWARATVVPL LIISHHRPIYALPGGGKGTSSDYLDELWCDPQNKMIPYNHDEPTAWRSDPFASIFTLADSILHRL DGLRSFNPFRRFALQKCVDWILEHQEDMGDIGDIMPPLHGAMLALRLEGYPLHSGPIHRGLEAI ERFAYRDKQGKRIQTTVSAFWDTSLMLIALGDAGMASKPWLTRSLGWLQQHQRLGNYGDWK VNNHGLKAGGFSFGYFNTWYPDVDDTASAVLAMIRQDERLVHSASVLDALNWLLGMQNTDG GWGAFDRDNDKHFLNKIPFSDMDALCDPSTPDVTGHVLEAFGLFLALSKADALADRVVAASRR AIRYLSDTHVLSRGWYGRWGCNYIYGTSAVLCALAYFGSENDALSGVRVMKDAINQAIRWLET VQNPDGGWGETVDSYKDPSRAGSGPSTASQTAWAIMALLPYLPPSTEVIQRGMEYLLRTQTK TASQGATWHEKAYTATGFPKYFYMGYSLYAHYFPMMALGRYAYPCPAWHENWRLKRD >seq_ID 97 MNDLSQAQPLDAILPDFADAAPSAPAPAVTGEAPTASLDAAITRATEAILAAQKPDGHWVYELE ADATIPAEYVLLVHYLGETPNLELEQKIARYLRRIQLPDGGWPLFTDGALDISASVKAYFALKMIG DPADAEHMVRAREAILAHGGAETVNVFTRILLALFGVVSWRAVPMMPVEIMLLPMWFPFHLSK VSYWARTVIVPLLVLNAKRPVARNPRRVRIDELFRGAPVNTGPRDRAPHQHAGWFRFFSGVD VLLRAVDGLFPKSTRERAVRQAVAFVDERLNGEDGLGAIFPAMANSVMMYDVLGYPADHPNR AIARQSIDKLLVIKDDEAYCQPCLSPVWDTSLAAHALLETGEAHAEQAAERGLAWLRPLQILDVR GDWISRRPNVRPGGWAFQYNNAHYPDVDDTAVVAMAMQRSATVTQSDVDRDAIARAREWVV GMQSSDGGWGAFEPENTQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQLGELPQNSEPAQ RAFDYMLKEQESDGSWYGRWGLNYIYGTWTALCSLNAAGLPHDDPRMKRAAQWLLSIQNED GGWGEGGESYKLDYHGYERAPSTASQTAWALMGLMAAGEVNHEAVARGVAYLEREQREHG LWDETRFTATGFPRVFYLRYHGYRKFFPLWALARFRHLKRNGLTRVAVGM >seq_ID 176 MNSVNATVAPIDDAALGGSIGAATRGLLDLKQPDGHFVFELEADATIPSEYVLLRHYLGEPVDA ALEAKIAVYLRRIQGAHGGWPLVHDGPFDMSASVKAYFALKMIGDSIDAPHMARAREAILSRGG AANVNVFTRFLLSLFEVLTWRSAPVLPIEIMLLPMWSPFHINKISYWARTTMVPLMVLAALKPRA RNPRGIGIRELFLQDPATVGTPKRAPHQSPAWFTLFNSLDWILRKIEPLFPKRLRARAIEKAIAFV EERLNGEDGLGAIFPPMVNTVMMYDALGFPPEHPPRAVARRGIDKLLVIGKDEAYCQPCVSPI WDTALTCHALLEAGGPEALSGAGKSLDWLLPKQELVLKGDWAVKRPDVRPGGWAFQYANAH YPDLDDTAVVVMAMDRVRRNDRSDKYNEAIARGREWIEGMQSRDGGFAAFDADNLEYYLNNI PFSDHAALLDPPTEDVTARCVSMLAQLGETVRSSPSMAAGVDYLRRTQLKEGSWYGRWGLN YIYGTWSVVCALNAAGVDHQDPAMRKAVDWLVSIQNADGGWGEDAVSYRLDYKGFEGAPTT ASQTAWALLALMAAGEVENPAVARGMKYLIDTQTKKGLWDEQRFTATGFPRVFYLRYHGYSR FFPLWALARYRNLRSTNSKVVGVGM >seq_ID 210 MDSGTFNPGGERGNTLDASIDAARAALLGYRRDDGHWVFELEADCTIPAEYVLLRHYLGEPID AALEAKIAVYLRRTQGAHGGWPLVYDGEFDMSATVKGYFALKMIGDSIDAPHMAKAREAILSR GGAVHANVFTRFLLAMFGILTWRAVPVLPVEIMLLPMWSPFHLNKISYWARTTIVPLMVLAALKP RAVNRLGVGLDELFLQDPKSIGMPARGPHQNRGLFALFGAIDAVLRVIEPLIPKKLRKHAIDRAV AFVEERLNGEDGLGAIYPPMANTVMMYKVLGYPEDHPPRAITRRGIDLLLVIGEEEAYCQPCVS PIWDTSLTCHALLEAGGAEAAQPVREGLDWLLPKQVLDLKGDWAVKAPNVRPGGWAFQYNN AHYPDLDDTAVVVMALDRARRDQPSAAYDNAIARGREWIEGMQSDDGGWAAFDVNNTEYYL NNIPFSDHGAMLDPPTEDVTARCVSMLAQLGETEQTSKAVARGVAYLRKTQLPDGSWYGRW GMNYIYGTWAVLCALNAAGVDHQDPAIRKAVAWLASIQNADGGWGEDGVSYRLDYRGYETAP STASQTAWALLSIMAAGEVDHPAVARGIEYLKGTQTEKGLWDEQRHTATGFPRVFYLRYHGYS KFFPLWGLARYRNLRATNSKVVGVGM >seq_ID 23 MTTGHRQFDDGLSERERLIHEAGLTLQRSMDYAYNVVRSDGHWCGEMSSNVTITAEYIFLRQA LGLDLKTDGAAYCRHILSQQNSDGSWGLAPEYPGDVSTTTEAYLALKMLGLSTDAPAMQQAK AFVLNAGGVAKVRVFTRIFLATFGLFPWKAVPQLPVELILLPSACPINIYKFASWARGTIAPLLIIC HHQPVYALPNGVFAENEYLDELWQDPTNKSEPYSPSIWELLSQGDITGLTFSLLDKLLYQLNGL RSIPLLRSYALKQCMKWILERQEPTGDWAGIFPPMHASVYAFVLEGYKLEDPPVRLGIEALENF AWEDAKGKRVQPCVSPVWDTTLMSIALSDAATPNHQIVDRAIQWIRDRQLLEPRGDWRVYRP RLAPGGFSFEYTNSHYPDIDDSAAIILAQVKHDPISANSSSVIAAATWILGMQNPDGGWAAFDV ENDKLFLNKIPFSDMDSLCDTSCADITGRILEAFGLLIRRVPDKDSSQLFQLLPAIRAACRRGIRY LASTQEANGAWFGRWGCNYIYGTSHALCGLAYFLQEDQQVPAMVQPALQWLKSQQNDDGG WGESLLSYQSPERKEQRSTASQTAWALMGLLAHLPHTDIVIERGIRWLVSSQRPVETLGSTWP EPVYTGTGFPNHFYLGYDYYRHYFPMMALGRYLRGVQG >seq_ID 91 MNDLSQAHVLGAAMPETAGEAQNAQAAANSAAAAAEASAVLAPSLDAAITRATDAILAAQKPD GHWVYELEADATIPAEYVLLVHYLGETPNVELEQKIARYLRRIQLPNGGWPLFTDGAIDISASVK AYFALKMIGDPVDAEHMVRAREAILAHGGAETVNVFTRILLALFGVVSWRAVPMMPVEITLLPM WFPFHLSKVSYWARTVIVPLLVLNAKRPLARNPRRVRIDELFRGAPVNTGMPARAPHQHVGWF GFFRVVDTVLRAVDGLFPKATRERAVREAVAFVDQRLNGEDGLGAIFPAMANSVMMYDVLGY PADHPNRAIARRSIEKLLVIKDDEAYCQPCLSPVWDTSLAAHALLETGDARAEQAAERGLAWLR PLQILDVRGDWISRRPNVRPGGWAFQYNNAYYPDVDDTAVVAMAMHRSEALTHSGADREAIA RAREWVVGMQSSDGGWGAFEPENTQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQLGEF PQNSEPAQRALDYMLKEQEADGSWYGRWGLNYIYGTWTALCSLNAAGLPHDDPRIRRAAQW LLSIQNEDGGWGEGGESYKLDYRGYERAPSTASQTAWALMGLMAAGEVDHEAVARGIEYLQR EQREHGLWDETRFTATGFPRVFYLRYHGYRKFFPLWALARYRHLKRNGLTRVAVGM >seq_ID 213 MDSGSYTTGVERNALEASIDAARSALLNYRRDDGHWVFELEADCTIPAEYVLLRHYLGEPVDA ELEAKIAVYLRRIQGAHGGWPLVHDGDFDMSASVKGYFALKMIGDSIDAPHMVRAREAIRSRG GAIHSNVFTRFLLTLYGVTTWRAVPVLPVEIMLLPSWSPFTLTKISYWARTTMVPLLVLCALKPQ AKNPKGVGIDELFLQDPKTIGMPVKAPHQNWALFKLFGSIDAVLRVIEPVMPKGIRKRAIDKALA FIEERLNGEDGMGAIFPPMANAVMMYEALGYPEDYPPRASQRRGIDLLLVDRGDEAYCQPCVS PVWDTALASHAVLEADGHEGAKSVRPALDWLLPRQVLDVKGDWAVKAPNVRPGGWAFQYNN AHYPDLDDTAVVVMALDRARKDQPNPAYDAAIARAREWIEGMQSDDGGWGAFDINNTEYYLN NIPFSDHGAMLDPPTEDVTARCVSMLAQLGETMDSSPALARAVGYLRDTQLAEGSWYGRWG MNYIYGTWSVLCALNAAGVPHADPMIRKAVAWLESVQNRDGGWGEDAVSYRLDYRGYESAP STASQTAWALLALMAAGEVDHPAVARGIEYLKSTQTEKGLWDEQRYTATGFPRVFYLRYHGY SKFFPLWALARYRNLQATNSKVVGVGM >seq_ID 196 MSMTSREDHDASSLISQVEHALKLSNDYALGLVHPDGHWYGEMNTNVTVTAEYVFLRQALRL DLKTDIAAYCHYLLSQQNSDGSWGLAPEYPGDVSTSTEAYLALKILGTSPHTPAMRNARAFVLK AGGIARVRIFTRIFLATFGLFPWSAVPELPVELMLLPSICPINIYKFASWARGTIAPLLIICHHQPVY SLPNGKSTDNDYLDELWVDCTNKSVPYGLPLWDLMSQGEFAGLAFGVLDKVLYQLNGLRSIPL IRAYARKQCIQWILERQEKTGDWAGIFPPMHANMYAFTLEGYKLDDDPVRLGFQALERFAWED EKGKRIQACVSPVWDTALMTIGLCDAMSPNKQTIDHALAWIRARQLLEPRGDWRVYRPQLAPG GFSFEYENSWYPDVDDTAAIILAQVKHDNGSIGSNSVIAAATWILGMQNPDGGWAAFDVENDK LFLNKIPFSDMDSLCDTSCADITGRILEAYGLMMMKYFSAKSDADPLLHTLRAACMRGMHYLAS TQEPNGSWYGRWGCNYIYGTSHVLCGLAYFVEKRLVCVMVKSALQWLKSRQNDDGGWGES LLSYQSPDREQQASTPSQTAWALMGLLSHLPVTDDAIERGIRYLVSSQRPEKGIGSSWPQAEY TGTGFPNHFYLGYDYYRHYFPMMALGRYLQGSRGLN >seq_ID 99 MNDLSQTQPLAAVLPEAADAPAVADASATAAPEPVQAASPSALDASITRATDTILAAQKPDGH WVYELEADATIPAEYVLLVHYLGETPNLELEQKIARYLRRIQLPNGGWPLFTDGALDISASVKAY FALKMIGDPVDAEHMVRARDAILAHGGAERANVFTRILLALFGVVSWRAVPMMPVEIMLLPVWF PFHLSKVSYWARTVIVPLLVLNAKRPLARNPRKVRIDELFRAAPVNTGMNERAPHQHAGWFGF FRCVDTVLRAVDGLLPKATRERAIRAAVAFVDERLNGEDGLGAIFPAMANSVMMYDVLGYPAD HPHRAIARKSLDKLLVIKDDEAYCQPCLSPVWDTSLAAHALLETGEARAEQAAERGLAWLRPL QILDVRGDWISRRPNVRPGGWAFQYNNAHYPDVDDTAVVAMAMHRSAALTQSDVDREAIARA REWVVGMQSSDGGWGAFEPENTQYYLNNIPFSDHGALLDPPTADVSGRCLSMFAQIGELPQS SEPARRAFDYMLQEQEPDGSWYGRWGLNYIYGTWTALSSLNAAGMPHDDPRMRRAAQWLV SIQNEDGGWGEGGESYKLDYHGYERAPSTASQTAWALLGLMAAGEVNHEAVARGIDYLQRE QREHGLWDETRFSATGFPRVFYLRYHGYRKFFPLWALARFRHLKRHGLTRVTVGM >seq_ID 85 MIRRMNKSAPSPWSALDAAIARGRDALVRLQQPDGSWCFELESDATITAEYILMMHFMDRIDD VRQERMARYLRANQRLDTHGAWDLYVDGAPDVSCSVKAYFALKAAGDSEHAPHMIRARDAIL KLGGAARSNVFTRILLATFGQVPWRAAPFMPIEFVLFPKWVPISMYKVAYWARTTMVPLLVLCS LKARARNPRNVSIRELFVTPPEQERHYFLPARGMRRLFLALDRTVRPIEPLLPKRLRQRAIRHAE AWCAERMNGEDGLGGIFPPIVYSYQMMQVLGYPDDHPLRRDCENALEKLLVTRPDGSMYCQ PCLSPVWDTAWSTMALEQARGVAAPETGDTASGALRELDERIARAYDWLATRQVNDLRGDWI ENAPADVEPGGWAFQYANPYYPDIDDTALVTAMLDRRGRTHRGADGTHPYASRVARALDWM RGLQSRNGGFAAFDADCDRMYLNAIPFADHGALLDPPTEDVSGRVLLCFGVTKRAADRASLAH AIDYVKRTQQPDGSWWGRWGTNYLYGTWSVLAGLALAGEDKSQPYITRALDWLRARQHADG GWGETNDSYIDPKLAGTNDGESTSNCTAWALLAQMAFGDCESDSVKRGIAYLQSVQQEDGF WWHRSHNAPGFPRIFYLKYHGYTAYFPLWALARYRRLAGAKDADATRSPASATPATDNALA >seq_ID 93 MIRAMNKSALSPWSALDTAIARGRDALARLQQPDGSWCFELESDATITAEYILMMHFMDRIDDA LQERMARYLRAIQRLDTHGAWDLYVDGAPDVSCSVKAYFALKAAGDSEHAPHMIRAREAILKL GGAARSNVFTRILLATFGQVPWRATPFMPIEFVLFPKWVPISMYKVAYWARTTMVPLLVLCSLK ARARNPRNVAIPELFVTPPDQERHYFPPTRGMRRAFLILDRVVRHVEPLLPKRLRRRAIRHAEA WCAQRMNGEDGLGGIFPPIVYSYQMMDVLGYPEDHPLRRDCENALAKLLVTRPDGSVYCQPC LSPVWDTAWSTMALEQARSVAVPESDESARALDELDARIARAYDWLATRQVNDLRGDWIENA PADTQPGGWAFQYANPYYPDIDDSAVVTAMLDRRGRTHRNADGSHPYAARVARALDWMRAL QSRNGGFAAFDADCDRLYLNAIPFADHGALLDPPTEDVSGRVLLCFGVTRRAEDRASLARAID YVKRTQQPDGSWWGRWGTNYLYGTWSVLAGLTLAGEDPSQPYIARALEWLRAHQHADGGW GETNDSYLDPALAGTNGGESTSNCTAWALLAQMAFGDCASDSVKRGIAYLQSVQQDDGFWW HRSHNAPGFPRIFYLKYHGYTAYFPLWALARYRRLAGAAEARARASSGRAPHAADTALA >seq_ID 168 MGKVETLHRMSTQDITLDDVERRVSLASKALMRLAGPDGHWCFELEADATIPSEYILYHHFRG SIPSAELEGKIANYLRRTQSAQHDGWSLVHDGPFDMSATVKAYFALKMIGDSIEAPHMRRARE AILRRGGAAHANVFTRTLLALYGEVPWSAVPVMPVEVMLLPRWFPFHLDKVSYWARTVMVPLF VLQAKKPRARNPRGIGIQELFVEPPERVKRWPAGPQESSPWRPVFAAIDKVLQKVEGSFPAGS RARAIDKAVAFVSERLNGEDGLGAIFPAMVNAVLMYEALGYPEDHPLVATARSSVEKLVTVKEH EAYVQPCLSPVWDTALSAHALMEAGGVEAERHAKRALDWLKPLQVLDIKGDWAASKPNVRPG GWAFQYANPHYPDLDDTAVVVMAMDRAQVRRSPGPDAADYGQSIARAREWVEGLQSRDGG WAAFDADNTYHYLNYIPFSDHGALLDPPTADVTARCVSMLAQLGETRESCPPLDRGVAYLLAD QEADGSWYGRWGMNYIYGTWSVLCALNAAGVDPASEPVRRAVNWLTTIQNPDGGWGEDAA SYKLEYRGYERAPSTASQTAWALLGLMAAGEADSPAVARGINYLTRSQGADGLWTEDRYTAT GFPRVFYLRYHGYAKFFPLWALARYRNLQQSNSRRVAVGM >seq_ID 184 MKKFGGMARTSLQAQSPGSNNTPSMDEKMLKAGLEAARGALLAQQREDGHWCFPLEADCTI PAEYILMMHFMDEVDLDLEVRIARFIREKQDVAHGGWPLYYGGEFDLSCSVKAYYALKIVGDSP DAPHMVRARAAILKHGGAARANVFTRLLLAMYDQLPWRGVPFVPVEIILFPKWFPFHTSKVAY WSRTVMVPLSILCSLKARAANPRKVAIRELFTVPPGEERNYFPVRTALNRVFLLIERTLSLLEPFI PQGVRRLALRRAESWIVERLNGDSGLGAIFPAMVNAGEALALLGYPYDHPAREQCRKALRLLL VEEGERTWCQPCVSPVWDTVLTCLAFQEDTEVDQKPIRKALDWLVPCQVLDAPADWQEDHP GLPGGGWAFQYANPHYPDLDDTAAVAWALYQADPKAYQESISRAADWLAGMQSSNGGFAAF DSDNTYYYLNEIPFADHGALLDPPTSDVSARCAGFLALYGQSRHKQALERSLAYLFNEQEASG AWFGRWGSNYIYGTWSVLEAFRLAGIDAGHPAIRRAVHWLKSVQREDGGWGESNDSYLSPQ QAGQFHTSTSFHTAWALLALMGAGEWRSHEVHRGIAYLLREQDSDGLWHEPWFTAPGFPRV FYLKYYGYTKYFPVWALTRFHALNRKFPG >seq_ID 12 MMYNNQWYFNQFNDIFCFPEQQKEYFPPTGTNISLNLKKRPDRQLLAHGASDLNGPFHLSQH NAFSAMLLAEVQKVLRLAVGHSLDLQRTDGAWCGEVHSNATFTAQYVFLQQQLGLPLDPTEIE GLSRWLFSQQNEDGSWGLGPGLGGDVSTTTETYLALKILGVSPEDPRMAAARSSIIKAGSLPA TRMFTRVFLASFGLIPWSAVPPLPAELILLPTLFPVNIYNLSSWARATCVPLLLIRHHEPLHSLPN GRHAENDFLDELWTKDIPRDFCYTTPLSRMWRLGDYAGIFFTSADHGLRFLGQYFNSPLRNLS RRKIINWILDHQEQSGEWAGYWPPQHNNIWALSLEGYSLDHPVLRRGIAAVKSFVLHDVTGMR AQVTVSQVWDTALMSIALSDSAPSTGIISPTQAIDWLMHHEVASHRGDWRVLRPKLATGGFCF EEFNTLYPDVDDTAAVIMALIKSNPAHLISGCVRRAAQWILGMQNRDGGWGAFDWNNDKFFLN KIPFSDMDSLCDPSTPDVTGRIIECFGMMMAGRHGYSLDGPLESRLRASSQLAIAYLLGCQENN GSWWGRWGVNYLYGTSNVLCGLAYYYDRSGLSKGDGKSNSHIVSAVDRASEWLKARQHSN GGWGEGPESYDSAQLAGCGQPTASQSAWVTMALLNYLSPTDEVIQRGISYLVRSQVKYGDES RATWPLERYTATGFPGHLYMEYDYYRHYFPIMALGRYVNKLSESHKLL >seq_ID 100 MIRRMTTPTPSPWSALDTAIARGRDALVRLQQPDGSWCFELESDATITAEYILMMHFMDKIDDL RQEKMARYLRANQRLDTHGGWALYVDGDPDVSCSVKAYFALKAAGDSEHAPHMVRARDAILK LGGAARANVFTRILLATFGQVPWRAAPFMPIEFVLFPKWVPISMYKVAYWARTTMVPLLVLCSL KARARNPRNISIRELFVTPPDEERQYFPPARGMRKLFLALDRTVRHVEPLMPKGLRQRAIRHAE AWCAERMNGEDGLGGIFPPIVYCYQMMEVLGYPDDHPLRRDCENALEKLLVTRPDGSMYCQP CLSPVWDTAWSTMALEQARGVAVAEDGEPGDARRALDERITRAYDWLAERQVNDLRGDWIE NAPADVQPGGWAFQYANPYYPDIDDTAVVTAMLDRRGRTHANADGTNPYATRVARALDWMR GLQSRNGGFGAFDADCDRLYLNAIPFADHGALLDPPTEDVSGRVLLCFGVTKRADEHASLARC IDYVKRTQQPDGSWWGRWGTNYIYGTWSVLAGLALAGEDKSQPYIARAIEWLRARQHADGG WGETNDSYIDPKLGGTNGGESTSNFTAWALLAQMAFGDCESDSVKRGIAYLQSVQQEDGFW WHRSHNAPGFPRIFYLKYFIGYTAYFPLWALARYRRLAGVANKRVSTADKTADAMA >seq_ID 84 MIRRMNQSAPSSWSALDAAIARGRDALVRLQQPDGSWCFELESDATITAEYILMMHFMDRIDD VRQEKMARYLRANQRLDTHGAWDLYVDGAPDVSCSVKAYFALKAAGDSEHAPHMIRARDAIL KLGGAARSNVFTRILLATFGQVPWRAAPFMAVEFVLFPKWVPISMYKVAYWARTTMVPLLVLC SLKARARNPRNVSIRELFVTPPEQERHYFPPARGMRRLFLALDRTVRPIEPLLPKRLRQRAIRH AEAWCAERMNGEDGLGGIFPPIVYSYQMMQVLGYPDDHPLRRDCENALEKLLVTRPDGSMYC QPCLSPVWDTAWSTMALEQARGVAAPETGDTATGAPRDLDGRIARAYDWLATRQVNDLRGD WIENAPADVEPGGWAFQYANPYYPDIDDTALVTAMLDRRGRTHRAADGTHPYASCVSRALDW MRGLQSRNGGFAAFDADCDRMYLNAIPFADHGALLDPPTEDVSGRVLLCFGVTKRAADRASL ARAIDYVKRTQQPDGSWWGRWGTNYLYGTWSVLAGLALAGEDKSQPYIARALDWLRARQHA DGGWGETNDSYLDPKLAGTNGGESTSNCTAWALLAQMAFGDCESDSVKRGIAYLQSVQQED GFWWHRSHNAPGFPRIFYLKYHGYTAYFPLWALARYRRLAGAKDAGATRSGASGASATSVTD DALA >seq_ID 86 MIRRMNKSAPSPWSTLDTAIARGRDALVRLQQPDGSWCFELESDATITAEYILMMHFMDRIDD VRQEKMARYLRANQRLDTHGAWDLYVDGAPDVSCSVKAYFALKAAGDSEQAPHMIRARDAIL KLGGAARSNVFTRILLATFGQVPWRAAPFMPIEFVLFPKWVPISMYKVAYWARTTMVPLLVLCS LKARARNPRNVSIRELFVTPPEQERRYFPPARGMRRLFLALDRAVRHIEPLMPKRLRQRAIRHA QAWCAERMNGEDGLGGIFPPIVYSYQMMQVLGYPDDHPLRRDCENALEKLLVTRPDGSVYCQ PCLSPVWDTAWSTMALEQARGVAAPETGETAAGTLRELDERIARAYDWLAARQVNDLRGDWI ENVPADVEPGGWAFQYANPYYPDIDDSALVTAMLDRRGRTHRHADGTNPYAPRVARALDWM RGLQSRNGGFAAFDADCDRMYLNAIPFADHGALLDPPTEDVSGRVLLCFGVTKRAEDRASLAR CIDYVKRTQQPDGSWWGRWGTNYLYGTWSVLAGLALAGEDKSQPYIARALDWLRARQHADG GWGETNDSYLDPTLAGTNGGESTSNCTAWALLAQMAFGDCESDSVKRGIAYLQSVQQEDGF WWHRSHNAPGFPRIFYLKYHGYTAYFPLWALARYRRLAGAAAAPPAALVAADTALA >seq_ID 80 MIRRMNKPAPSPWSALDTAIARGRDALMRLQQPDGSWCFELESDATITAEYILMMHFMDKIDD ARQEKMARYLRAIQRLDTHGGWDLYLDGDPDLSCSVKAYFALKAAGDSEHAPHMVRARDAIL KLGGAARSNVFTRILLATFGQVPWRATPFMPIEFVLFPKWVPISMYKVAYWARTTMVPLLVLCS LKARARNPRNIAIPELFVTPPDQERQYFPPARGMRRAFLALDRVVRHVEPLLPKRLRQRAIRHA QAWCAERMNGEDGLGGIFPPIVYSYQMMDVLGYPDDHPLRRDCENALEKLLVTRPDGSMYC QPCLSPVWDTAWSTMALEQARGVAVPEAGAPAGALDELDARIARAYDWLAERQVNDLRGDW IENAPADTQPGGWAFQYANPYYPDIDDSAVITAMLDRRGRTHRNADGSHPYAARVARALDWM RGLQSRNGGFAAFDADCDRMYLNAIPFADHGALLDPPTEDVSGRVLLCFGVTKRADDRASLA RAIDYVKRTQQPDGSWWGRWGTNYLYGTWSVLAGLALAGEDPSQPYIARALAWLRARQHAD GGWGETNDSYIDPALAGTNAGESTSNCTAWALLAQMAFGDGESESVKRGIAYLQSVQQDDGF WWHRSHNAPGFPRIFYLKYHGYTAYFPLWALARYRRLAGGASSAGAHTVPASTGADAALA >seq_ID 82 MNKPAPSPWSALDTAIARGRDALMRLQQPDGSWCFELESDATITAEYILMMHFMDKIDDVRQE KMARYLRAIQRLDTHGGWDLYVDGDPDVSCSVKAYFALKAAGDSEHAPHMVRARDAILALGG AARSNVFTRILLATFGQVPWRATPFMPIEFVLFPKWVPISMYKVAYWARTTMVPLLVLCSLKAR ARNPRNIAIPELFVTPPDEERHYFPPARGMRRAFLALDRVVRHVEPLLPKRLRQRAIRHAQAWC AERMNGEDGLGGIFPPIVYSYQMMDVLGYPDDHPRRRDCENALEKLLVTRTDGSMYCQPCLS PVWDTAWSTMALEQARAVAVPEAGARASALDELDARIARAYDWLAERQVNDLRGDWIENAPA DTQPGGWAFQYANPYYPDIDDTAVVTAMLDRRGRTHRNADGSHPYAARVARALDWMRGLQS RNGGFAAFDADCDRMYLNAIPFADHGALLDPPTEDVSGRVLLCFGVTKRAADRASLARAIDYV KRTQQPDGSWWGRWGTNYLYGTWSVLAGLALAGEDPSQPYIARALAWLRARQHADGGWGE TNDSYIDPTLAGTNAGESTSNCTAWALLAQMAFGDCESESVRRGIAYLQSVQQDDGFWWHRS HNAPGFPRIFYLKYHGYTAYFPLWALARYRRLASGVSSAGVHAVPASTGADAALA >seq_ID 108 MNDLSQTQPRDAVLPEAAGAVPPASAPAPAAASEAPAASLDTAITRATDAILAAQKPDGHWVY ELEADATIPAEYVLLVHYLGETPNVELEQKIARYLRRIQLPDGGWPLFTDGAPDVSASVKAYFAL KMIGDPADAEHMVRAREAILANGGAEAVNVFTRILLALFGVVSWRAVPMMPVEIMLLPMWFPF HLSKVSYWARTVIVPLLVLNAKRPLARNPRRVRIDELFRGAPVNTGPRDRAPHQHAGWFRFFS GVDMLLRAVDGLFPKATRERAVRAAVAFVDERLNGEDGLGAIFPAMANSVMMYDVLGYPADH PNRAIARQSIEKLLVIKDDEAYCQPCLSPVWDTSLVAHALLETGEARAEQAAERGLAWLRPLQIL DVRGDWISRRPNVRPGGWAFQYNNDYYPDVDDTAVVVMAMHRSAALTHSEVDREAIARARE WVVGMQSSDGGWGAFEPENTQYYLNNIPFSDHGALLDPPTADVSGRCLSMLAQLGELPQGS EPAQRAFAYMLKEQEPDGSWYGRWGLNYIYGTWTALCSLNAAGMPHDDPRMKRAAKWLLSI QNEDGGWGEGGESYKLDYHGYERAPSTASQTAWALMGLMAAGEVNHEAVARGVAYLQREQ REHGLWDETRFTATGFPRVFYLRYHGYRKFFPLWALARFRHLKRHGLTRVAVGM >seq_ID 169 MREAAVSKVETLQRPKTRDVSLDDVERGVQNAARALTEMTQTDGHICFELEADATIPSEYILFH QFRGTVPRDGLEAKIGNYLRRTQSKVHGGWALVHDGPFDMSATVKAYFALKMIGDDIEAPHM RAARKAILQRGGAANANVFTRILLALYGEVPWAAVPVMPVEVMHLPKWFPFHLDKVSYWARCT MVPLEVIQAKKPRAKNPRGIGVAELFVTPPDSVRTWPGSPHATWPWTPIFGAIDRVLQKTQDH FPKVPRQRAIDKAVAWVSERLNGEDGLGAIFPSMVNSVLMYEVLGYPPDHPQVKIALEAIEKLV AEKDDEAYVQPCLSPVWDTALTSHAMLETGGAAAEANARAGLDWLKPLQILDIKGDWAETKPN VRPGGWAFQYANPHYPDLDDTAVVVMAMDRAQRQHGLVSGMPDYSASIARAREWVEGLQS ADGGWAAFDADNNHHYLNHIPFSDHGALLDPPTADVTARVVSMLSQLGETRETSRALDRGVT YLLNDQEKDGSWYGRWGMNFIYGTWSVLCALNAAGVDPQSPEIRKAVAWLIRIQNPDGGWG EDASSYKLNPEFEPGYSTASQTAWALLALMAVGEVDDPAVARGVNYLMRTQGQDGLWNEER YTATGFPRVFYLRYHGYPKFFPLWAMARFRNLKKGNSRQVQFGM >seq_ID 163 MREAAVSKVETLQRPKTRDVSLDDVERGVQSAARALTDMTQADGHICFELEADATIPSEYILFH HFRGTEPRAGLEAKIGNYLRRTQSKVHGGWALVHDGPFDMSASVKAYFALKMIGDDIEAPHM RAVRKAILQRGGAANANVFTRILLALYGEVPWTAVPVMPVEVMHLPKWFPFHLDKVSYWARCT MVPLEVIQAKKPRAKNPRGVGVAELFVTPPDSVRTWPGSPHATWPWTPIFGAIDRVLQKTQDH FPKVPRQRAIDKAVAWVSERLNGEDGLGAIFPSMVNSVLMYEVLGYPPDHPQVKIALEAIEKLV AEKDDEAYVQPCLSPVWDTALTSHAMLEVGGTQAEANARAGLDWLKPLQILDIKGDWAETKP NVRPGGWAFQYANPHYPDLDDTAVVVMAMDRAQRQHGLVSGMPDYSTSIARAREWVEGLQ SADGGWAAFDADNNHHYLNHIPFSDHGALLDPPTADVTARVVSMLAQLGETRETSRALDRGV TYLLNDQEKDGSWYGRWGMNFIYGTWSVLCALNAAGVDPQSPEIRKAVAWLIRIQNPDGGWG EDASSYKLNPEFEPGYSTASQTAWALLALMAVGEVDDPAVARGVNYLMRTQGADGLWNEER YTATGFPRVFYLRYHGYPKFFPLWAMARFRNLKRGNSRQVQFGM >seq_ID 105 MKPNHTFSPAALDAAILRGRDTLSGLQQPDGSWCFELESDATITAEYILMMHFMDKIDEVRQAQ MARYLRAIQRVETHGAWDLYVDGAPDISCSVKAYFALKAAGDSEHAPHMIRAREAILKLGGAAR SNVFTRILLATFGQVPWRAAPFMPVEFVLFPKWVPISMYKVAYWARTTMVPLLVLCSLRARAR NPRNVSIAELFVTPPDEERHYFPPAKGMRKLFLALDRTVRHLEPLLPRRLRQRAIRHAEAWCAE RMNGEDGLGGIFPPIVYSYQMMEVLGYPEDHPLRRDCEDALEKLLVTRADGSVYCQPCLSPV WDTAWSTMALEQARGATPAAPDTQVSERELDARIARAYDWLATRQVNDLEGDWRENARPGT LPGGWAFQYANPYYPDIDDSAVVTAMLDRRGRAQARASGENPYAERVTRALDWMRGLQSRN GGFGAFDADCDRLYLNAIPFADHGALLDPPTEDVSGRVLLCFGVTKRPADRAAAARAIEYVKRT QQPDGSWWGRWGTNYLYGTWSVLAGLALSGEDKSQPYIARALDWLRAHQHADGGWGETN DSYADPRLRATNYGESTSNCTAWALLAQMAFGDWQSDSVRRGIAYLLSVQQDDGFWWHRSH NAPGFPRIFYLKYHGYTAYFPLWALARYRRLAGAQAAPSSPGPGTAATIADPAVA >seq_ID 211 MTSGTTILGAERGRTLDASIDAARAALLGYRRDDGHWVFELEADCTIPAEYVLLRHYLGEPVDA ALEAKIAVYLRRTQGAHGGWPLVHDGEFDVSATVKAYFALKMIGDSIDAPHMAKAREAILARGG AIHVNVFTRFLLSMFGILTWRSVPVLPVEIMLLPMWAPFHLNKISYWARTTIVPLMVLAALKPRA VNKLDIGLDELFLQDPQSIGMPAKAPHQSWGLFTLFGSIDAVLRVIEPLIPKKLRSYAIGRAVAFIE ERLNGEDGLGAIYPPMANTVMMYKVLGYGEDHPPRAITRRGIDLLLVVGEEEAYCQPCVSPIW DTSLTCHALLEAGGAEAALPVRKGLDWLIPKQVLDLKGDWAVKAPNVRPGGWAFQYNNAHYP DLDDTAVVVMALDRARRDQPSAAYDNAIARGREWIEGMQSDDGGWAAFDVNNTEYYLNNIPF SDHGALLDPPTEDVTARCVSMLAQLGETAETSSALARGVAYLRKTQLAEGSWYGRWGLNYIY GTWSVLCALNAAGVAHQDPAMRKAVAWLASIQNADGGWGEDAVSYRLDYRGYESAPSTASQ TAWALLALMAAGEVDHPAVARGVEYLKGTQTEKGVWDEQRYTATGFPRVFYLRYHGYSKFFP LWALARYRNLRATNSKVVGVGM >seq_ID 76 MDSVNATAREAKESKISESEILESSIASATQGVLGFQQSDGHWVFELEADCTIPAEYVLLRHYLA EPVDTVLEAKIGNYLRRVQGAHGGWPLVHDGEFDMSASVKAYFALKMIGDSIDAPHMVRAREA IHARGGAIHSNVFTRFMLAMFGIVTWRAVPVLPIEIMLLPFWSPFHINKISYWARTTMVPLMVIAA LKPRAKNPKGVGIDELFLQDPRSIGMTAKAPHQSMAWFLLFRSLDAILRVIEPLFPKSLRKRAID TALAFSEERLNGEDGMGAIYPPMANLVMMYDALGKDENYPPRAVTRRGIDKLLVIGDDEAYCQ PCVSPVWDTTLTAHALLEAGGDKAGPAAKHGLDWLIPKQELEVKGDWAVKRPDVRPGGWAF QYNNAYYPDLDDTAVVVMSMDRMRREHGVTGYDSAIDRGREWIEGMQSDDGGWAAFDVNN LEYYLNNIPFSDHGALLDPPTEDVTARCVSMLAQLGETAKTSKHVADGVAYLRKTQHPEGSWY GRWGMNFIYGTWSVLCALNMAGVRHDDPMIRKAADWLASIQNKDGGWGEDTVSYRLDYKG WEAAPSTASQTAWALLALMAAGEVDHPAVARGVEYLIATQNEKGLWDEQRYTATGFPRVFYL RYHGYSKFFPLWGLARYRNLRNTNSRVVGVGM >seq_ID 179 MEQQPELISGGVGGVAYPWDLGSQAIEEAILAARAALLAHLHPDGYWCFELEADCTIPAEYIMM MHYTGELEAALELKLARYIRECQLQEGGWPLYYGGAMDISCSVKAYFALKLAGDDPEAAHMRR ARKAVLERGGAVNANVFTHIALALFGEIPWRGVPFMPPEILLLPRWFPFHLSKVSYWSRTVMVP LFILAAHKPRARNPRAIHISELFVTDPQLETGYFKARSRLNRLFITLDALGRRIEPFIPRAVRAKAL RRAAEWFITRLNGEHGLGAIFPAMVNSYEALELLGYAADHPLRQQVRKGLRDLVVEQADRAYC QPCLSPIWDTALACLALQEADRGSSSAQVRHALDWLQARQLLDTPGDWSEQHPSLPGGGWP FQFRNDHYPDLDDTAIVAWAMQRASDPERYGAAIRRATVWLLGMQSANGGFAAFDSDNTRYY LNEIPFADHGALLDPPTSDVTARVVALLGSLDGEVHDRSALNRAVAFLHREQEAEGCWYGRW GTNYIYGTWSVLTALEQLGYDFNAPWVRKAVIWLKSVQRDDGGWGESNDTYLDHRPQDRQA DESTPFQTAWAVLALIAAGECRSPEVWRGVEYLLRHQRPDGLWYCPWFTAPGFPRVFYLKYH GYDAYFPLMALARYRNCVLDNDA >seq_ID 81 MIRRMNKPAPSPWSALDAAIARGRDALMRLQQPDGSWCFELESDATITAEYILMMHFMDKIDD ARQEKMARYLRAIQRLDTHGGWDLYVDGDPDVSCSVKAYFALKAAGDSEHAPHMVRARDAIL ALGGAARSNVFTRILLATFGQVPWRAAPFMPIEFVLFPKWVPISMYKVAYWTRTTMVPLLVLCS LKAHARNPRNIAIPELFVTPPDQERHYFPPARGMRRAFLALDRVVRHAEPLLPKRLRQRAIRHA QAWCAERMNGEDGLGGIFPPIVYSYQMMDVLGYPADHPLRRDCENALEKLLVTRPDGSMYC QPCLSPVWDTAWSTMALEQARGVAVHEAGAPASALDELDARIARAYDWLAERQVNDLRGDWI ENAPADTQPGGWAFQYANPYYPDIDDSAVVTAMLDRRGRTHRNADGTHPYAARVARALDWM RGLQSRNGGFAAFDADCDRMYLNAIPFADHGALLDPPTEDVSGRVLLCFGVTKRADDRASLA RAIDYVKRTQQPDGSWWGRWGTNYLYGTWSVLAGLALAGEDPSQPYIARALAWLRARQHAD GGWGETNDSYIDPALAGTNAGESTSNCTAWALLAQMAFGDGESESVKRGIAYLQSVQQDDGF WWHRSHNAPGFTRIFYLKYHGYTAYFPLWALARYRRLAGGASSAGAHAVPASTAADAALA >seq_ID 22 MATLTTMATTATMATTEASQPLEAQARTALTKATSYAWEIISNRHWCGELESNVTVTCEHIFFL YVLYQHIDPDEGSQYRQWLLSQQNADGSWGIAPNYPGDVSTSAEAYLALRIIGMSPDSPELFQ ARTFIRAAGGLSKMRMFTRIFFAEFGLVPWTAIPQLPAEFILVPAHFPISIYRLASWARSNVVPLLI IAHHRPLYPLPNGLHKQNPFLDELWLDPATKPLPYGSLDPTDPLSFVFTILDKALSYLGGLRRCP TRGYARRRCIQWILQHQEKAGDWAGIIPPMHAGIKALWLEGYKLHDEPIQLGLAAIERFTWTDN RGKRLQCCISPVWDTVLMIRALQDTPASLGIKSDPRIADALAWTAENQHRGPEGDWRVYQPNI PVGGWAFEYSNTWYPDIDDTAAAVLAFLTHDPATARSRLVRDAVLWIVGMQNADGGWAAFDH ENNRLFLNKIPFSDMESLCDPSTPDVTGRTIECLGMLRDLLMLPAEKAGKKGEKYGYPDGERD AAADSHLLKIINTACARAIPYLIRTQEATGAWYGRWAVNYVYGTCLVLCGLQYFKHDPTFAPEID TMATRAVKWLRQIQNSDGGWGESVLSYREPWRAGCGPSTPSQTAWALMGLLTVCGGEDRS VQRGVRHLVDTQDDILSKGEGGAAAWTEREFTSTGFPNHFYISYTLYRVYFPITALGRYLSLVE GGKKENGGGA >seq_ID 178 MNSINATAAPIDDNVLGDRIGAATRGLLSLKQSDGHFVFELEADATIPSEYILMRHYLGEPVDTV LEAKIAAYLRRIQGAHGGWPLVHDGPFDMSASVKAYFALKMAGDSIDAPHMARAREAILSRGG AANVNVFTRFLLSFFGELTWRSVPVLPVEIMLLPMWSPFHLNKVSYWARTTMVPLMVLAALKP RARNPRGIGIRELFLEDPATVGTPKRAPHQSPGWFALFTGFDRVLRLIEPLSPKWLRARAMKKA IAFVEERLNGEDGLGAIFPPMVNTVMMYDALGFPPEHPPRAVTRRGIDKLLVVGENEAYCQPC VSPIWDTALSCHALLEAGGPEAVNSAGKCLDWLLLKQELVLKGDWAVKRPDVRPGGWAFQYA NGHYPDLDDTAVVVMAMDRVRRNGPNGRYDEAIARGREWIEGMQSRDGGFAAFDADNLEYY LNNIPFSDHAALLDPPTEDVTARCVSMLAQLGETVDSSSSMAAGVEYLRRTQLAEGSWYGRW GLNYIYGTWSVLCALNVAGVDHQDPVIRRAVNWLVSIQNADGGWGEDAVSYRLDYKGFEGAP TTASQTAWALLALMAAGEVENPAVARGIKYLIDTQTKKGLWDEQRYTATGFPRVFYLRYHGYS KFFPLWALARYRNLRSTNSKAVGVGM >seq_ID 177 MNATVAQIGDAVLEDRIGSATRGLLNLKQSDGHFVFELEADATIPSEYILLRHYLGEPVDTVLEA KIAAYLRRIQGAHGGWPLVHDGPFDMSASVKAYFALKMIGDSVDAPHMARAREAILSRGGAAN VNVFTRFLLSFFEVLTWRSVPVLPVEIMLLPMWSPFHLNKISYWARTTMVPLMVLAVLKPRARN PRDVGIRELFLQDPATVRTPKRAPHQSPAWFALFSSLDWILRRIEPLFPKRLRARAMEKAIAFVE ERLNGEDGLGAIFPPMVNTVMMYDALGFPPEHPPRAVTRRGIDKLLVIGEDEAYCQPCVSPIW DTALSCHALLEAGAPEALNSAGKCLDWLLPKQELVLKGDWAAKRPDVRPGGWAFQYANGHY PDLDDTAVVVMAMDRVRRNGRGDKYDEAIERGREWIEGMQSRDGGFAAFDADNLEYYLNNIP FSDHAALLDPPTEDVTARCVSMLAQLGATVDGSSSMAAGVEYLRRTQLAEGSWYGRWGLNYI YGTWSVLCALNAAGVDHQDPAIRKAVDWLLSIQNEDGGWGEDAVSYRLDYKGFEGAPTTASQ TAWALLALMAAGEVENPAVTRGIKYLIDTQTKKGLWDEQRYTATGFPRVFYLRYHGYSKFFPL WALARYRNLRSTNSKVVGVGM >seq_ID 170 MREAVSKVEALQRSKTQGISLEDVERGVAQATRALTALAHDDGHICFELEADATIPSEYILFHHF RGTQVPGDLEAKIGNYLRRTQGRHGGWALVHEGPFDMSCTVKAYFALKMIGDDIEAPHMRRA REGILSRGGAANANVFTRFMLALYGEVPWRAVPVMPVEVMFLPKWFPFHLDKISYWARTTVVP LFVLQATKPRARNPRGISVQELFVTPPESVRSWPGSPHATWPWTPIFGFIDRVLQRVENHLPR KSRQRAMEMARAWVSERLNGEDGLGAIFPAMVNSVLMYEVMGYRPDHPQVRVACDAIEKLV VEKADEAYVQPCVSPVWDTALASHALLEAGGPEAEAQARAGLDWLKPRQVLDIVGDWAARKP KVRPGGWAFQYANAHYPDLDDTAVVVMAMDRAMHQHGLVAGMPDYKASIARAREWVEGLQ SEDGGWAAFDADNNHMYLNHIPFSDHGALLDPPTADVTARVVGMLSQLGETRETSRALDRGV NYLLNDQEEDGSWYGRWGMNFIYGTWSVLCALNAAGVDPADPRIQKAVSWLIRIQNPDGGW GEDASSYKIDPAFEPGSSTASQTAWALLALMAAGAVDDRAVTRGINFLTRTQGADGFWKEERY TATGFPRVFYLRYHGYPKFFPLWAMARFRNLKRGNSRRVQFGM >seq_ID 14 MLLAEVQKALRLAVGHSLDWRADGAWCGEVHSNATFTSQYVFLQQQIGLPLDPTEIEGLSRW LFSQQNEDGSWGLGPGLGGDVSTTTETYLALKILGVSPEDPRMAAARTSIIKAGSLPATRMFTR VFLASFGLIPWSAVPPLPAELILLPTLFPVNIYNLSSWARATCVPLLLIRHHEPLHSLPNGRHAEN DFLDELWTKDIPRDFCYTTPLSRMWRLGDYAGIFFTSADHGLRFLGQYFHSPLRNLSRRKIINWI LDHQEQSGEWAGYWPPQHNNIWALSLEGYSLDHPVLRRGIAAVKSFVLHDATGMRAQVTVSQ VWDTALMSIALSDSAPSTGIISPTQAIDWLMHHEVASHRGDWRVLRPKLATGGFCFEEFNTLYP DVDDTAAVIMALIKSNPAHLISGCVRRAAQWILGMQNRDGGWGAFDWNNDKFFLNKPFSDMD SLCDPSTPDVTGRIIECFGMMMAGRHGYSLDCQLENRLRASSQLAIAYLLGCQENNGSWWGR WGVNYLYGTSNVLCGLAYYYDRSSLSKGDVKSNSNIVSAVDRASEWLKARQHSNGGWGEGP ESYDNAQLAGCGQPTASQSAWVTMALLNYLSPTDEVIQRGVSYLVRNQVKYGDESRATWLLE RYTATGFPGHLYMEYDYYRHYFPIMALGRYVNKLSGSHKLL >seq_ID 180 MTRALRQAPESAGAIGIAAASPATETSGQDTHPREISGAITAARDALLKLQQADGHWCFMLEAD CTIPAEYILWTHFTGELEPEIERKLAARLRAKQASHGGWPLYEGGDLDISCSVKVYYALKLVGD DPNAPHMRRAREAILAQGGGARANVFTRLALAMFSQIPWRGVPFIPVEIMLLPRWFPFHLSKVS YWSRTVMVPLAILYSLKAQAQNPRNVHIQELFTVPPEQERHYFPVRSRLNKILLSVERTARLLEP LIPSMLRRRALKKAETWFTERLNGEDGLGGIFPAMVNAHESLILLGYSPDHPWRVQAKKALQNL VIEEKNSASCQPCLSPIWDTGLAALALQETEGGHTTAPVIRALDWLKERQILEQSGDWQVQHP NLKGGGWAFQYNNSYYPDLDDTALVAWSMDQAATPERYGEAIGRACDWLCGMQSRNGGFA AFESDNTHYYLNEIPFADHGALLDPPTADVTARCIVLLGRLNKPQYAETLQRALDYLRREQEPN GSWFGRWGTNYIYGTWSALTALEQANIDPQEGFIRKAVEWLKQVQRLDGGWGEDNYSYFDS SLAGRYQESTPVHTAWALLALMAVGEANSEAVKKGIAYLLQIQQEDGLWDHPAFNAPGFPRVF YLKYHGYDKFFPLWALARYRNHLNRQC >seq_ID 155 MMANATDTIELPPSRAADRIVPMTDIDQAVDAAHAALGRRQQDDGHWVFELEADATIPAEWLL EHYLDRIDPALEERIGVYLRRIQGDHGGWPLYHGGKFDVSATVKAYFALKAIGDDIDAPHMARA RAAILDHGGAERSNVFTREQLALFGEVPWHATPVMPVELMLLPRKALFSVWNMSYWSRTVIAP LLVLAALRPRAINPRDVHVPELFVTPPDQVRDWIRGPYRSQLGRLFKYVDIALRPAERLIPDATR QRAIKAAVDFIEPRLNGEDGLGAIYPAMANTVMMYRALGVPDSDPRAATAWEAVRRLLVELDG EAYCQPCVSPIWDTGLAGHAMIEAASGPKGIRPEDTKKKLAAAAEWLRERQILNGEGRLGDQL PRRAPRRLGLPVQQRLLPRRGRHGSGRHVLHREGDPANDEALERARQWIIGMQSSNGGWGA FDIDNNLDFLNHIPFADHGALLDPPTADVTARCISFLAQLGHPEDRPVIERGIAYLRTDQEREGC WFGRWGTNYIYGTWSVLCAYNAAGVAHDDPSVVRAVDWLRSVQREDGGWGEDCASYEGAT PGIYTESLPSQTAWAVLGLMAVGLRDDPAVMRGMAYLTRTQKDDGEWDEEPYNAVGFPKVEY LRYHGYRQFFPLLALSRYRNLASSNSRHVAFGF >seq_ID 8 MNRMLQPLHSGAGIFRSSLDRVIAQARQALGGRQAEDGHWCFEFEADCTIPAEYILMQHYMD ERDEALEARIAVYLRGKQADHGGWPLYYGGHFDLSASVKVYYALKLAGDDPELPHMRRAREAI LAHGGAERSNVFTRITLALFAQVPWRAVPFIPVEIMLLPRWFPFHIYKVASWSRTVMVPLFILCS LKARAKNPLQVHIRELFRRPPDQITDYFSHARRGIVAYIFLSLDRFWRLMEGWIPHGIRRRALKK AEAWFTARINGEDGLNGIFPAMVNAHEALELLGYPPDHDYRRQTGAALRKLVVERANDAYCQP CVSPVWDTCLALHALLEEDGEVSPAVQNGIRWLKNRQIGAEPGDWRESRPHLAGGGWAFQY ANPYYPDLDDTAAVGWALARAGRAEDRDSIEKAANWLAGMQSRNGGFGAYDVDNTHYYLNEI PFADHKALLDPPTADVTGRVVAFLAHLARPRDRDVLRRAVAYLLREQESSGAWFGRWGTNYIY GTWSVLMALAELNDPSLKPTMERAAYWLRAVQQGDGGWGESNDSYSDPGLAGMGQTSTAA QTAWACLGLMAAGDRDSVALHRGIAWLQAHQEGDGCWQAPFFNAPGFPKVFYLIYHGYAFYF PLWALARYRNLGCMAHE >seq_ID 203 MSMNEAVLAAPRAAVATAAPALQAPIEALSPLDAGIGHAVDALLAQQNADGHWVYELEADATIP AEYVLMVHYLGETPDLSLEARIARYLRRIQNADGGWPLFHEGRSDISASVKAYFALKMAGDDP QAAHMARAREVILAMGGAETSNVFTRTLLALYGVMPWQAVPMMPVEIMLLPQWFPFHLSKVS YWARTVIVPLLVLNSLRPQARNPRKVGIDELFLGSRDAVRLPPRAPHQHKGWHALFHGADVLL RTAEHVMPRGLRRRAIDAAKAFVRERLNGEDGLGAIFPAMANSVMMFDVLGVPPDDPDRAIAR RSIDKLLVVHGDEAYCQPCLSPVWDTALAAHALLEASEPRATAAVTRALDWLRPLQVLDVRGD WTVRRPDVRPGGWAFQYANPHYPDVDDTAVVVAAMHRAARTDHSGRADPNAEATARAIEWI VGMQSANGGWGAFEPENTHLYLNNIPFADHGALLDPPTADVSARCLSMLCQTGATPDKSEPA ARALQYLLAEQLPDGSWFGRWGTNYIYGTWSALCALNAAGLGPDAPPLRRAAEWLVAIQNPD GGWGEDGDSYKLEYRGYETAPSVASQTAWALLALMAAGQAAHPAVTRGIDYLLRTQQADGL WHEPRFTAVGFPRVFYLRYHGYARYFPLWALARYRNLERSGNRQVAWGL >seq_ID 165 MREAAVSKVETLQRPKTRDVSLDDVERGVQSATRALTEMTQADGHICFELEADATIPSEYILFH QFRGTEPRPGLEAKIGNYLRRTQSKVHGGWALVHDGPFDMSASVKAYFALKMIGDDIEAPHM RAVRKAILQRGGAANANVFTRILLALYGEVPWAAVPVMPVEVMHLPKWFPFHLDKVSYWARCT MVPLFVIQAKKPRAKNPRGVGVAELFVTPPDSVRTWPGSPHATWPWTPIFGGIDRVLQKTQDH FPKVPRQRAIDKAVAWVSERLNGEDGLGAIFPAMVNSVLMYEVLGYPPEHPQVKIALEAIEKLV AEKEDEAYVQPCLSPVWDTALNSHAMLEAGGHQAEANARAGLDWLKPLQILDIKGDWAETKP NVRPGGWAFQYANPHYPDLDDTAVVVMAMDRAQRQHGLVSGMPDYSESIARAREWVEGLQ SADGGWAAFDADNNHHYLNHIPFSDHGALLDPPTADVTARVVSMLSQLGETRATSRALDRGV TYLLNDQEKDGSWYGRWGMNFIYGTWSVLCALNTAGVDPQSPEIRKAVAWLIRIQNPDGGWG EDASSYKLNPEFEPGYSTASQTAWALLALMAAGEVDDPAVARGVNYLVRTQGQDGLWSEER YTATGFPRVFYLRYHGYPKFFPLWAMARFRNLKRGNSRQVQFGM >seq_ID 181 MSISPTFSGSSLQKSSLSDHSTISEPFTVVDRVNGISAVALDDAITRARSALLAQQREDGHWCF SLEADCTIPAEYILMMHFMDEIDTALERRIANFLRNRQVTDGHGGWPLYYGGDFDMSCSVKVY YALKLAGDSPEAAHMVRARNAILERGGAARSNVFTRLLLAMYRQIPWRGVPFVPAEIMLLPRW FPFHLSKVAYWSRTVMVPLSILCTLKAKAANPRNIHVRELFTVDPEMEKNYFPVRTPLNHLLLYL ERLGSKLEPLIPSFIRRRALKKAEQWTIERLNGRDGLGAIFPAMVNAYEALTLLGYDHDHPLLQQ CRLALRELLVNEGEDITWCQPCVSPVWDTVLASLALQEDERADNGPVRHALDWLVPLQALDQ PGDWRNSRPDLPGGGWAFQYANPHYPDLDDTAAAAWALCQADTEDYRTSITRAADWLAGM QSSNGGFAAFDIDNVHYYLNEIPFADHGALLDPPSSDVTARCIGLLALNGEARHQETVKRGLTF LFNEQEPSGAWFGRWGTNYVYGTWSVLEALKLARVDHDHQAVKRAVQWLKSVQRADGGWG ETNDSYLDSELAGQLETSTSFQTAWAVLGLMAAGEVGSTAVRNGIDYLIRTQSAAGLWEEPWF TAPGFPKVFYLKYHGYSKYFPLWALNRYRAMNSRSVV >seq_ID 110 MILFPAGFYFSIYEISYWSRCIVVPLSIAIARKPHVTVGDDLLKELYLVPREDVVYRIERDQDGFC WYNFFIDADSIFRRYEQHPIKFIRRIAKKMAEKWLLEHMEKSGGLGAIWPAMINSIFAMKCLDYP DDHPALTAQMKEVEALVIYEGDMLYLQPCVSPVWDTAWSIIAMNDSGIPGSHPVLQKAGKWLL SKEVRDFGDWKLKCKVEEPSGWYFQYANEFYPDTDDTGAVLMALQRVSLPEDMHKEKTLLRA LRWLQAMQCDDGGWGAFDRNNNKTILNNIPFADFNALLDPSTSDVTGRCIEFFGRIGFNKTYL NIKKAVEFLKKEQDEDGSWFGRWGSNYIYGTWSVISGLIAVGEDINKAYIKKAIAWLKSVQNSD GGWGETIKSYEDSALKGIGKSTPSQTAWALLTLITAGEIKSSSTERGIDFLLSTQKEDGSWDER EFTATGFPKVFYLKYHMYRNYFPLMALGRYRHFTHKLATSQ >seq_ID 182 MSISQAFFRTLIQKSSLSDSSLVSENFPADDVAGNEANEISAVTLDEAITRAYTALLAQQREDGH WCFPLEADCTIPAEYILMMHFMDEVDTVLERKIANFLRTRQVTDGHGGWPLYYGGDFDMSCS VKTYYALKLAGDSPEAAHMVHARNAILERGGAARSNVFTRLLLAMYRQIPWRGVPFVPAEIMLL PRWFPFHLSKVAYWSRTVMVPLSILCTLKAKAINPRNVHVQELFVVDPVKEKNYFPVRTSLNRL LLYVERLASKLEPFIPSFIRRRAVKKAEQWVIERLNGNDGLGAIFPAMVNAYEALTLLGHDRDHP LLQQCRQSLRELLVDEGEEITWCQPCVSPVWDTVLATLALQEDKQADSEPIRRALDWIVPLQIL DEPGDWRDSRPNLLGGGWAFQYANPHYPDLDDTAAVAWALIQTGAEDYRVSITRAADWLAG MQSSNGGFAAFDIDNAYYYLNEIPFADHGALLDPPTSDVSARCVGLLALNGEVRHQEAVKRGL DFLFNEQESSGAWFGRWGSNYIYGTWSVLEAFRLARVDKGHQAVQRAIQWLESVQRADGGW GETNDSYLDPQLAGQLEASTSFQTAWAVLGLMAAGEVENTAVRKGIDYLLRTQIATGLWEEPW FTAPGFPRVFYLKYHGYSKYFPLWALNRYRTLSSKSAV >seq_ID 162 MSPFLQASDDNNPLFKESCQALDHATEFARDTLVNKEHWCGWVLSNVTVTAEWIFLQYILGLE MSNEDRRGFLKHFTSSQRPDGSWSLATQTTTGGELSCTIEAYLALKILGVSPEEDYMVRARDY VRSHGGAEKMRMLSRFHLAMFGLIPWAAVPQMPPELIFMPSWSLVNIYKFSSWARCNIVGLCM LRVHEPLYALPNGKQLDNDYLDELWLDPYHKAIPYTVPYLQLMQTSPLGVLFQLGDLFLWLLSF LGFWFLRRWAVSSSIQWTLDHQEPSGDWGGIYPPMHHNILALMLEGWSQDDPVIQRGIGACQ RFLAEDPAHGKWMQPSVSPVWDTFLMIRAVADAKTTDDADKLLVKPVDWVLAQQIDDDHIGD WRIYRPDIPAGGFAFEYFNKWYPDVDDTAVGVVALMRHDPSLVNDDRILKAAAWTLGMQNRD FGWAAFDADNNAFYLHATPFSDMDSLTDSSTPDVTGHVLEMLGLMYRLERQGRVKSPEMLAF LSQSHGACDRGLGYLLGSQEAFGGWYGRWGVNYIFGTSAALCALAYFADRKGVRGKMAAGA DWLRSRQNPDGGWGELLESYDNKALAGRGRSTPSQTAWALQGLLELEDPRGEVVEAGVNW LLRHQVTSPSRNSGRVSATWPEDDYTATGFPGHFYLKYELYCHYFPMMALARYRSCIQDGA >seq_ID 172 MDDRVGAATFEAQPRAGFGSVEAAISRAREALLAVQKPDGHFVFELEADVSIPAEYILFRHFLG DPAKTEIERKIGVYLRRRQTAAGGWPLFAEGVFNVSSSVKAYFALKIIGDDPNAPHMAKARNAIL AHGGAAQSNVFTRSLLALYGEVPWRAVPAMPVEIMHLPRWFPFHLSKVSYWGRTVIAPLIVVH ALKPRAKNPRKISVSELFVAPAETVSRWPGAPHKSFPWTTIFGAIDRVLHKTEPLLPARSHQTAI DKAVAFVTARLNGEDGLGAIYPAMAYSAMMFFALGAPLSDPRIVQIRKAIDRLLVIKDGEAYCQP CVSPVWDTALASHALMESAGQRPEARTAPAAAAVFEALDWLKPLQVLDVKGDWATQNPDVR PGGWAFQYANPHYPDLDDTAVVVLAMDRAVKTSPLIAGEEETAYVEAISRAREWILGLQSANG GFGAFDADNDRDYLNYIPFADHGALLDPPTADVTARCVSMLGQLGERPETSPALARAIDYLLSE QEEEGSWFGRWGMNYIYGTWSVLSAFNAVERPADCAATRKAAAWLKRIQNPDGGWGEDGE SYALGYKGYNPAPSTASQTAWALLALMAAGEVDAPEVALGLDYLVSTQADDGFWDEARFTAT GFPRVFYLRYHGYAKFFPLWAMARYRNLKSGNRLKTQFGM >seq_ID 24 MLGAIREPPIDVQIALHSRDDNQTGLVLRGTRRTVDRVLKGLCSSPCFFCSVSLTMATLTTTMA TTATMATTEASKPLEAQARTALTKATNYAWEIFSNRHWCGELESNVTVTCEHIFFLYVLYQHID PGEGSQYRQWLLSQQNSDGSWGIAPNYPGDISTSAEAYLALRIIGMSTDSPELYRARTFIRAAG GLSKMRMFTRIFFAEFGLVPWTAIPQLPAEFILVPAHFPISIYRLASWARSNVVPLLIIAHHRPLYP LPNGLHKQNPFLDELWLDPATKPLPYGSSDPTDPVAFVFTILDKALSYLGGLRRSPTRGYARRR CVQWILQHQEKAGDWAGIIPPMHAGIKALLLEGYKLHDEPIQLGLAAIERFTWADNRGKRLQCC ISPVWDTVLMIRALQDTPASLGIKLDPRIADALAWTAENQHRGPEGDWRVYKPNIPVGGWAFE YHNTWYPDIDDTAAAVLAFLTHDPATARSRLVRDAVLWIVGMQNADGGWAAFDHENNQLFLN KIPFSDMESLCDPSTPDVTGRTIECLGMLRDLLMRPAENAENGEKYGYPDGEGDAAADAHLLQ IINTACARAIPYLIRSQEATGTWYGRWAVNYVYGTCLVLCGLQYFKHDPKFAPEIQAMAARAVK WLKQVQNSDGGWGESLLSYREPWRAGCGPSTPSQTAWALMGILTVCGGEDRSVQRGVRHL VDTQDDTLSQGDGGAAAWTEREFTIREPLHEASQRIGSD >seq_ID 26 MATLTTTMATTATMATTEASKPLEAQARTALTKATNYAWEIFSNRHWCGELESNVTVTCEHIFF LYVLYQHIDPGEGSQYRQWLLLQQNSDGSWGIAPNYPGDISTSAEAYLALRIIGMSTDSPELYR ARTFIRAAGGLSKMRMFTRIFFAEFGLVPWTAIPQLPAEFILVPAHFPISIYRLASWARSNVVPLLI IAHHRPLYPLPNGLHKQNPFLDELWLDPATKPLPYGSSDPTDPVAFVFTILDKALSYLGGLRRS PTRGYARRRCVQWILQHQEKAGDWAGIIPPMHAGIKALLLEGYKLHDEPIQLGLAAIERFTWAD NRGKRLQCCISPVWDTRVYKPNIPVGGWAFEYHNTWYPDIDDTAAAVLAFLTHDPATARSRLV RDAVLWIVGMQNADGGWAAFDHENNQLFLNKIPFSDMESLCDPSTPDVTGRTIECLGMLRDLL MRPAENAENGEKYGYPDGEGDAAADAHLLQIINTACARAIPYLIRSQEATGTWYGRWAVNYVY GTCLVLCGLQYFKHDPKFAPEIQAMAARAVKWLKQVQNSDGGWGESLLSYREPWRAGCGPS TPSQTAWALMGILTVCGGEDRSVQRGVRHLVDTQDDTLSQGDGGAAAWTEREFTSTGFPNH FYISYTLYRVYFPITALGRYLSLIEGGQEKKKKGGGT >seq_ID 171 MGKVETLHRTSTQDITLDDVERRVTLASKALMRLANADGHWCFELEADATIPSEYILYHHFRGSI PTAELEGKIAAYLRRTQSAQHDGWALIHDGPFDMSATVKAYFALKMVGDPIDAPHMRRARDAIL RRGGAAHANVFTRIMLALYGEVPWTAVPVMPVEVMLLPRWFPFHLDKVSYWARTVMVPLFVL QAKKPRARNPRGIGIRELFVEAPERVKRWPAGPQESSPWRPVFAAIDKVLQKVEGFFPAGSRA RAIDKAVAFVSERLNGEDGLGAIFPAMVNTVLMFEALGYPDDHPFAVTARSSVEKLVTVKEHEA YVQPCLSPVWDTALAAHALMEAGGTEAERHAKRAMDWLKPLQVLDIKGDWAASKPDVRPGG WAFQYANPHYPDLDDTAVVVMAMDRVQSRRSPGPDAADYGLSIARAREWVEGLQSRDGGW AAFDADNTYHYLNYIPFSDHGALLDPPTADVTARCVSMLSQLGETRETCPPLDRGVAYLLADQ EADGSWYGRWGMNYIYGTWSVLCALNAAGIDPACEPVRRAVTWLTAIQNPDGGWGEDASSY KLEYRGYERAPSTASQTAWALLALMAAGEADNPAVARGINYLTRTQGADGLWAEDRYTATGF PRVFYLRYHGYAKFFPLWALARYRNLQRGNSLKVAVGM >seq_ID 173 MLREATAISNLEPPLTASYVESPLDAAIRQAKDRLLSLQHLEGYWVFELEADCTIPAEYILMMHF MDEIDAALQAKIANYLRHHQSADGSYPLFRGGAGDISCTVKVYYALKLAGDSIDAPHMKKARE WILAQGGAARSNVFTRIMLAMFEQIPWRGIPFTPVEIMLLPKWFPFHLDKVSYWSRTVMVPLFIL CSHKVTARNPSRIHVRELFTVEPQKERHYFDHVKTPLGKAILALERFGRMLEPLIPKAVRKKATQ KAFDWFTARLNGVDGLGAIFPAMVNAYEALDFLGVPPDDERRRLARESIDRLLVFQGDSVYCQ PCVSPIWDTALTSLTLQEVARHTADLRLDAALSKGLKWLASKQIDKDAPGDWRVNRAGLEGGG WAFQFGNDYYPDVDDSAVVAHALLGSEDPSFDDNLRRAANWIAGMQSRNGGFGAFDADNTY YYLNSIPFADHGALLDPPTADVSARCAMFLARWVNRQPELRPVLERTIDYLRREQEADGSWFG RWGTNYIYGPGAVLLAYEGRRVPNDDPSVRRAVAWLKSIQREDGGWGEDNFSYHDPSYRGR FHTSTAFQTGFALIALMAAGEXGSPEVQAGVDYLLRQQRPDGFWNDECFTAPGFPRVFYLKY HGYDKFFPLWALARYRNERYALA >seq_ID 117 MNETAFANPAPQVGPAQRQPAAPQEAPAARLPAPALDRGIDRALDALLHQQRPDGHWVYELE ADATIPAEYVLMVHYLGEDPDRDLEARIARYLRRIQNPDGGWPLFHQGRSDISASVKAYFALKM AGDDPQSAPMQRARQAIHAMGGAEATNVFTRTLLALYGVLPWKAVPMMPVEIMLLPRWFPFH LSKVSYWARTVIVPLLVLNSLRPQARNPRGVGINELFVGNCHTVGLPPRAAHQHAGWYTVFRG LDALLRLAEPLFPRTLRRRAIAAAQRFVRERLNGEDGLGAIFPAMANSVMMFDVLGVPPEDPAR AVARRSIERLLVEHGDEAYCQPCLSPVWDTALATHALLETGEARAAQAAGRALDWLRPLQVLD LRGDWAVRRPLVRPGGWAFQYANAYYPDVDDTAVVAAAMDRFMRAHHAPGRYGEAVARAT EWIVGMQSGNGGWGAFEPENTHLYLNNIPFADHGALLDPPTADVSARCLSMLCQTGATPANS EPAARALRYLLAEQMPDGSWFGRWGTNYIYGTWSALCALNAAGLPPEAPELCRAVAWLARIQ NADGGWGEDGSSYRLDYSGYEPAPSVASQTAWALLALMAAGAAQHPAVARGIDYLLRTQQP GGLWHEPRFTAVGFPRVFYLRYHGYARYFPLWALARYRNLQRGLGDHGGNSGQVAWGL >seq_ID 204 MSMNETAFATAVPRIAPASAGDSPAPRDAAQALDQGIGRAIDALLHQQRPDGHWVYELEADAT IPAEYVLMVHYLGEAPDLELEARLARYLRRIQNPDGGWPLFHEGRSDVSASVKAYFALKMAGD DPQAAHMQRARRAVHALGGAEASNVFTRTLLALYGVMPWLAVPMMPVEIMLLPQWFPFHLSK VSYWARTVIVPLLVLNSLRPQARNPRGVGINELFVGNCHTVGLPPRAAHQHAGWYTVFRGLDA LLRVAEPLVPRTLRRRAIAAAQAFVRERLNGEDGLGAIFPAMANSVMMFDVLGVPPDDPARAL ARQSVERLLVEHGDEAYCQPCLSPVWDTALAAHALLETGEARATAAAGRGLDWLRPLQVLDV RGDWAVRRPLVRPGGWAFQYANAYYPDVDDTAVVAAAMNRYMRAHDVPGRYDEAVARAAE WIVGMQGGDGGWGAFEPENTHLYLNNIPFADHGALLDPPTADVSARCLSMLCQIGATPGKSE PAARALRYLLAEQMPDGSWFGRWGTNYIYGTWSALCALNATGLAPEAPEMRRAVAWLEQIQN ADGGWGEDGSSYRLDYRGYEPAPSVASQTAWALLALMAAGAAQHAAVARGIDYLLRTQQSG GLWHEPRFTAVGFPRVFYLRYHGYARYFPLWALARYRNLQRGGAHQVPWGL >seq_ID 79 MRIGTTTNPSMPFPLSSSGAVFYREVNELREVQQEINRIQAFLLQRQQEDGTWRFCLESSPMT DSHMIILLRTLGIHDERLMEKLTAHITALQHDNGAWKLYPDEQEGHLSTTIDSYYALLLSGKYTK NEPRMALARSFILEKGGLTQANMLTKFATALTGQYQWPSHFLVPVEIALLPPSFPVSFYDFVGY ARVHLAPMMIVADRNYVKKPDNAPDLSDLYADTPISRGLYPHRFLENFLKEGQSFLATIHDSLQ QLPFLPGQLHKLALRRLEQYILARIEPDGTLYNYSTSTFFMIFALLARGFSPKDPLIQKAMQGLTG SVYDYENGAHLQLATSAVWDTALLTFSLQKSGLSPTHPAIQKANRYLLRKQQHTYGDWKIRNP NGKPGGWGFSDYNTMNPDIDDTTAALRSLRLLARTDVTAATAWKRGLEWLLSMQNDDGGWP AFERNTDADFIRHLPIEGADTVSTDPSSADLTGRTLEFLGNYAGRTLTDLHVEKGVRWLLKHQE SDGSWYGRWGIAYLYGTWAAITGLMAVGFSPTEPAIQKAVAWLVANQNPDGGWGESCQSDL KKTYVPLGASTPSQTAWAIDALIAVSSKPTAELQRGIRYLLTHNQANDWTTRYPTGGGRPGGT YFAYHSYRWIWPLLALSHYQVKYANT >seq_ID 70 MLLYDKVHEEIERRTTALQTMQRQDGTWQFCFEGALLTDCHMIFLLKLLGRNDEIEPFVKRLVS LQTNEGTWKLYEDEKGGNLSATIQAYAALLASEKYSKEDMNMRRAEMFIKEHGGVSRAHFMT KFLLAIHGEYEFPALFHFPTPILFLQDDSPLSIFGLSSSARIHLIPMMICMNKRFRVEKKLLPNLNHI AGGGGQWFREERSPLIQSFLGDVKKVISYPLSLHHKGYEEVERFMKERIDENGTLYSYASATF YMIYALLALGHSIQSPIIEKAVTGLKSYIWKMDRGSHLQNSPSTVWDTALLSYSLQEAKVTNENK MIQRATEYLLQKQQTKKVDWSVHASSLVAGGWGFSDVNTTIPDIDDTTAALRALARSRGNDRV DDAWGRGVEWVKGLQNNDGGWGAFERGVTSKLLSNLPIENASDMITDPSTPDITGRVLELFG TYAPNELLEEQKKKAIKWLMDVQEQNGSWYGKWGICYIYGTWATMTGLRALGVPSTHPALKK AASWLEHLQHEDGGWGESCQSSVEKKFISLPFSTPSQTAWALDALISYYDQETPIIRKGISYLLA QSTMNEKYPTGTGLPGGFYIRYHSYGHIYPLLALAHYVKKYRK >seq_ID 140 MAGERSALITALKRSQAADGSWRFPFETGISTDAYMIILLRTLDINDEPLIQALVERIESRQEANG AWKLFADEGDGNVTATVEAYYALLYSGYRQPTDRHMQKAKRRILDMGGLDRVHLFTKVMLAL TGQYPWPGRFPLPLEFFLLPPSFPLNMYDLSVYGRANMIPLLIAADSRYSRKTDKSPDLSDLFA SRGDWGMPESRSLLTYVKRSLIGLPAQLHQAAKQRAVRYLFEHIEPDGTLYSYFSSTFLFIFALL ALGYRNDDPRIRQAVRGLRSLRTTIDGHVHLQYTTASVWNTALASYTLQEAGVPMTDRAIEKA NRYLLSRQNVRYGDWAVHNPYSTPGGWGFSDVNTMNPDVDDTTAALRAIRQAAAKETAFRH AWDRANQWLFSMQNDDGGFAAFEKNVSSRFWRYLPIEGAEFLLMDPSTADLTGRTLEYFGTF AGLTKDQRAVSRAVDWLLSHQERNGSWYGRWGICYIYGTWAAITGLTAVGVPAHHPALQKAV RWLLSIQNDDGGWGESCKSDGAKTYVPLGDSTPVHTAWALDALVAAAERPTLEMKAGFRALF RLLHHPDWTASYPVGQGMAGAFYIHYHSYRYIFPLLALAHYEQKFGPLDD >seq_ID 137 MAGERSALITALKRSQAADGSWRFPFETGISTDAYMIILLRTLDINDEPLIQALVERIESRQEANG AWKLFADEGDGNVTATVEAYYALLYSGYRQPTDRHMQKAKRRILDMGGLDRVHLFTKVMLAL TGQYPWPGRFPLPLEFFLLPPSFPLNMYDLSVYGRANMIPLLIAADSRYSRKTDKSPDLSDLFA SRGDWGMPESRSLLTYVKRSLIGLPAQLHQAAKQRAVRYLFEHIEPDGTLYSYFSSTFLFIFALL ALGYRNDDPRIRQAVRGLRSLRTTIDGHVHLQYTTASVWNTALASYTLQEAGVPMTDRAIEKA NRYLLSRQNVRYGDWAVHNPYSTPGGWGFSDVNTMNPDVDDTTAALRAIRQAAAKETAFRH AWDRANQWLFSMQNDDGGFAAFEKNVSSRFWRYLPIEGAEFLLMDPSTADLTGRTLEYFGTF AGLTKDQRAVSRAVDWLLSHQERNGSWYGRWGICYIYGTWAAITGLTAVGVPAHHPALQKAV RWLLSIQNDDGGWGESCKSDGAKTYVPLGDSTPVHTAWALDALVAAAERPTLEMKAGFRALF RLLHHPDWTASYPVGQGMAGAFYIHYHSYRYIFPLLALAHYEQKFGPLDD >seq_ID 136 MVADERSALIDALKRSQSVDGSWRFPFETGISTDAYMIILLRTLGIHDEPLIQALVERIESRQDAN GAWKLFADEGDGNVTATVEAYYALLYSGYRKKTDSHMQKAKARILEVGGLERVHLFTKVMLAL TGQHSWPRRFPLPLVFFLLPPSFPLNMYDLSVYGRANMVPLLVVAERRYSRKTDNSPDLSDLA ASRNDWRLPDTEALWSYVKRSLTGLPAWLHRAAEQRAVRYMLEHIEPDGTLYSYFSSTFLLIFA LLALGYPKDDPHIARAVRGLRSLRTEIDGHTHMQYTTASVWNTALASYALQEAGVPPTDRTIEK ANRYLLSRQHIRYGDWAVHNPYGVPGGWGFSDVNTMNPDVDDTTAALRAIRRAAAKETAFRH AWDRANRWLFSMQNDDGGFAAFEKNVGKRFWRYLPIEGAEFLLMDPSTADLTGRTLEYFGTF AGLTKDHSAIARAIDWLLDHQEADGSWYGRWGICYVYGTWAAVTGLSAVGVPIDHPAMQKAV RWLLSIQNDDGGWGESCKSDGAKTYVPLGASTPVHTAWALDALIAAAERPTPEMKAGVRALV RMLHHPDWTASYPVGQGMAGAFYIHYHGYRYIFPLLALAHYEQKFGPFVD >seq_ID 49 MLLYEKVYEEIARRTTALQTMQRQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKRLAS LQTNEGTWKLYEDEVGGNLSATIQSYAALLASEKYTKEDANMKRAEMFINERGGVARAHFMTK FLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPNLNHI AGGGGEWFREDRSPVFQTLLSEVKKIITYPLSLHHKGYEEVERFMKERIDENGTLYSYATASFY MIYALLALGHSIQSPIIQKAITGIASYIWKMERGSHLQNSPSTVWDTALLSYALQEAQVPKASKVI QNASAYLLRKQQTKKVDWSVHAPNLFPGGWGFSDVNTMIPDIDDTTAVLRALARSRGDENVD NAWKRAVNWVKGLQNNDGGWGAFEKGVTSRILANLPIENASDMITDPSTPDITGRVLEFFGTY AQNELPEKQKQSAINWLMNVQEENGSWYGKWGICYIYGTWAVLTGLRSLGIPSSDPSLKRAAL WLEHIQHEDGGWGESCQSSVEKRFVTLPFSTPSQTAWALDALISYYEKETPIIRKGISYLLSNPY VNEKYPTGTGLPGGFYIRYHSYAHIYPLLTLAHYTKKYRK >seq_ID 62 MNIVIRISKGWVSNLLLDEKAHEEIVRRATALQTMQWQDGTWRFCFEGAPLTDCHTIFLLKLLG RDKEIEPFVERVASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASKKYTKEDANMKRAENFIQ ERGGVARAHFMTKFLLAIHGEYEYPSLFHVPTPIMFLQNDSPFSIFELSSSARIHLIPMMLCLNKR FRVGKKLLPNLNHIAGGGGEWFREDRSPVFQTLLSDVKQIISYPLSLHHKGYKEIERFMKERIDE NGTLYSYATASFYMIYALLALGHSLQSSMIQKAIAGITSYIWKMERGNHLQNSPSTVWDTALLSY ALQEAQVSKDNKMIQNATAYLLKKQHTKKADWSVHAQALTPGGWGFSDVNTTIPDIDDTTAVL RALARSRGNKNIDNAWKKGVNWIKGLQNNDGGWGAFEKGVTSKLLAKLPIENASDMITDPSTP DITGRVLEFFGTYAQNELPEKQIQRAINWLMNVQEENGSWYGKWGICYIYGTWAVMTGLRSLG IPSSNPSLTRAASWLEHIQHEDGGWGESCHSSVEKRFVTLPFSTPSQTAWALDALISYYDTETP AIRKGVSYLLSNPYVNERYPTGTGLPGAFYIRYHSYAHIYPLLTLAHYIKKYRK >seq_ID 59 METLIDPEISRLTQRLLEDQEEDGAWRYCFENSLMTDAYMIVLIRSLGIKKERLVQELADRLLSQ QEEKGFWKIYRDEVEGNLSATVEAYFALLWSGAVKEKDENMVKARDCILSGGGLDKVHSMTK FMLAAHGQYPWDRFFPVPVEVILLPTYFPVSFTDFSAYARVHLAPLLLLKSERYIRKTSTTPDLS YLLKDQEDFSFFREEERSFIEYVTSGVEAIAAFPANLNDLAKKTALNYMLARLEPDGSLYSYFSS SFYMIIALLSQGYSRKDPLVVNAIKALISYQCKGDGYPHIQNSPSTIWDTALISHALQSSGVDSRN AQILKASHYLYRHQHTQKGDWASEAPQTAPGGWGFSESNTINPDVDDTTAALRALKLDAYTDP VKRMAWNRGVKWALSMQNKDGGWPAFEKNKNKDILSWVPMDGAEDAALDRSCADLTGRTL EFLGNDAGMGRENSQVLKGIEWLMNNQENDGSWYGKWGICYIYGTWAALTGMMAAGMSAD HQSIIKAIKWLYQIQNSDGGWGESCRSDKERKYISLGASTPSQTAWALDALISINDHPTKEIDRGI ESLVRLLNTDDWRKEYPTGAGLPGRFYIHYHSYPYIWPLLALSNYKTKFLEVR >seq_ID 51 MVLYGRVCAEIERTITALHTMQQQDGAWRFCFEGSPLTDCHMIFLLRLLEKEEEIEPFVARLTSI QTNEGTWKLYEDERAGNVSTTIQAYAALLASGMYTKEDVNMKRAEAFIQERGGIARSHFMTKF LLALHGGYEYPRMFYFPTPILFLPEDSPLSIFELSSSARIHLIPMMICMNKRFTVSKTILPNLDHIS GSSKSEWFREDRSSLFETILGEVKKFVTYPLSLHHKGDKEAERFMIERIDRNGTLYSYASATFY MIYALLALGHHIQSPLIQQAVAGLRTYKWHMEAGIHLQNSPSTVWDTALLSYALQEANVNESTP MIQTATEYIWQRQHHEKKDWSLHAPTLSPGGWGFSDVNTTIPDVDDTTAALRALARSRKRNR RIEEAWKKGVNWKKGLQNKDGGWAAFEKGVTNRFLTHLPLENSGDMMTDPSTADITGRVLEF FGTYAPNELQDHQKNRAITWLMDVQENNGSWYGKWGVSYIYGTWAALTGLRAVGVANTHPA LKKAVMWLERIQHRDGGWGESCRSSIEKRFVPLSFSTPSQTAWAIDALISYYDEETPVIRKGISY LLEHAASHQEYPTGTGLPNGFYIRYHSYSYMYPLLTFAHYINKYRK >seq_ID 32 MLLYEKAHEEIVRRATALQTMQWQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVERVA SLQTNEGTWKLHEDEVGGNLSATIQSYAALLASKKYTKEDANMKRAENFIQERGGVARAHFMT KFLLAIHGEYEYPSLFHLPTPIMFLQNDSPFSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPNLN HIAGGGGEWFREDRSPVFQTLLSDVKQIISYPLSLHHKGYEEIERFMKERIDENGTLYSYATASF YMIYALLALGHSLQSSMIQKAIAGITSYIWKMERGNHLQNSPSTVWDTALLSYALQEAQVSKDN KMIQNATAYLLKKQHTKKADWSVHAPALTPGGWGFSDVNTTIPDIDDTTAVLRALARSRGNKNI DNAWKKGGNWIKGLQNNDGGWGAFEKGVTSKLLAKLPIENASDMITDPSTPDITGRVLEFFGT YAQNELPEKQIQRAINWLMNVQEENGSWYGKWGICYLYGTWAVMTGLRSLGIPSSNPSLTRA ASWLEHIQHEDGGWGESCHSSVEKRFVTLPFSTPSQTAWALDALISYYDTETPAIRKGVSYLLS NPYVNERYPTGTGLPGAFYIRYHSYAHIYPLLTLAHYIKKYRK >seq_ID 31 MSTIHENVRSRQKKTISLLRETQNADGSWSFCFEGPILTNAFLILLLTSLGDNDKELIAELAEGIR AKQRPDGTFANYPDDRKGNVTATVQGYAGLLASGLYSRSEAHMIQAERFIISNGGLRNVHFMT KWMLAANGLYPWPALHLPLSFLVIPPTFPLHFYQFSTYARIHFVPMAVTLNKRFSLKNPNVSSL AHLDRHMTKNPFTWLRSDQDENRDLSSLFAHWKRLLQIPAAFHQLGLRTAKTYMLDRIEEDGT LYSYASATIFMVYGLLALGVSRHSPVLRKALAGTKALLTSCGNIPYLENSTSTVWDTALLNYALM KSGISDNDQMITSAARFLRERQQKKVADWAVHNPHAEPGGWGFSNINTNNPDCDDTAAVLKAI PRKLYPASWERGLSWLLSMQNSDGGFSAFEKNVNHPLVRLLPLESAEEAAIDPSTSDLTGRVL HCLGEAGLSSDHPQIEKAVQWLIRHQEEDGSWYGRWGVCYIYGTWAALTGMKACGVSQNHP AVKKAIRWLKSIQNEDGSWGESCKSAEEKTYVPLSYGTLVQTAWAAEALLQYEKTHHQAVTKG ISFLIENRHYEGAAFSYPTGIGLPKQFYIRYHSYPYVFSLLALSTFMKMSEKEEEK >seq_ID 48 MLLYEKAHEEIARRATALQTMQRQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKRLAS LQTNEGTWKLYEDEVGGNLSATIQSYAALLASKKYTKEDANMKRAENFIKERGGVARAHFMTK FLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMVCLNKRFRVGKKLLPNLNHI AGGGGEWFREDRSPLFQTLLSDVKQIISYPLSLHHKGYEEVERFMKERIDENGTLYSYATASFY MIYALLALGHSLQSSLIQKAIAGITSYIWKMERGSHLQNSPSTVWDTALLSYALQEAHVPKDHKM IQQTITYLLKKQHTKKADWSVHALALTPGGWGFSDVNTTIPDVDDTTAVLRALARSRGNENIDN AWKKGVNWIKGLQNNDGGWGAFEKGVTSKLLANLPIENASDMITDPSTPDITGRVLELFGTYT QNELPKKQKQSAINWLMNVQERNGSWYGKWGICYIYGTWAVMTGLRSLGIPSNNPSLKRAAL WLEHIQHEDGGWGESCQSSVEKRFVTLPFSTPSQTAWALDALISYYDKETPTIRKGVSYLLAN PYVNEKYPTGTGLPGGFYIRYHSYAQIYPLLTLAHYTKKYQK >seq_ID 34 MNIVIRISKGWVSNLLLYEKVHEEIARRTTALQSMQRQDGTWRFCFEGAPLTDCHMIFLLKLLG RDKEIEPFVKRLASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASEKYTKEDANMKRAEMFIN ERGGVARAHFMTKFLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKR FRVGKKLLPNLNHIAGGGGEWFREDRSPVFQTLVSDVKKIITYPLSLHHKGYEEVERFMKERID ENGTLYSYATASFYMIYALLALGHSLQSSMIQKAIAGITSYMWKMESGNHVQNSPSTVWDTALL SYALQEAHVLKDNKMLQNATAYLLKKQHTKKADWSVHAPALTPGGWGFSDVNTTVPDVDDTT AVLRVLARSRGNEKVDHAWQKGINWVKGLQNNDGGWGAFEKGVTSHILANLPIENASDMITD PSTPDITGRVLEFFGTYAQNELPEKQKQSAINWLMNVQEENGSWYGKWGICYIYGTWAVLTGL RSLGIPSSDPSLKRAALWLEHIQHEDGGWGESCQSSVEKRFVTLPFSTPSQTAWALDALISYY DKETSVIRKGISYLLSNPYINETYPTGTGLPGGFYIRYHSYAHIYPLLTLAHYAKKYRK >seq_ID 47 MLLYEKVHEEIVRRATALQTMQWQDGTWRFCFEGAPLTDCHMIFLLKLLGREKEIEPFVERIAS LQTNEGTWKLYEDEVGGNLSATIQSYAALLASKKYTKEDANMKRAENFIKERGGVARAHFMTK FLLAIHGGYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPNLNHI AGGGGEWFREDRSPVFQTLISDVKQIISYPLSLHHKGYEEIERFMKERIDENGTLYSYATASFY MIYALLALGHSPQSSMIQKAIAGLTSYIWKMGRGSHLQNSPSTVWDTALLSYALQEARVSKDNK MIQNATAYLLKKQHTKKADWSVHAPALIPGGWGFSDVNTTIPDIDDTTAVLRALARSRGNKNID NAWQKGVNWIKGLQNNDGGWGAFEKGVTSKLLANLPIENASDMITDPSTPDITGRVLEFFGTY AQNGLPEKQKQSAINWLMNAQEENGSWYGKWGICYIYGTWAVMTGLRSLGIPSSNPSLKRAA SWLEYIQHEDGGWGESCHSSVEKRFVTLPFSTPSQTAWALDALISYYDTETPAIRKGVSYLLSN PYVNERYPTGTGLPGAFYIRYHSYAHIYPLLTLAHYLKKYRK >seq_ID 52 MRSILEDVKAFRQKTLAELQNRQRSDGSWRFCFEGPVMTDSFFILMLTSLGDQDSSLIASLAER IRSRQSEDGAFRNHPDERAGNLTATVQGYTGMLASGLYDRKAPHMQKAEAFIKDAGGLKGVH FMTKWMLAANGLYPWPRAYIPLSFLLIPSYFPLHFYHFSTYARIHFVPMAITFNRRFSLKNNQIG SLRHLDEAMSKNPLEWLNIRAFDERTFYSFNLQWKQLFQWPAYVHQLGFEAGKKYMLDRIEE DGTLYSYASATMFMIYSLLAMGISKNAPVVKKAVSGIKSLISSCGKEGAHLENSTSTVWDTALIS YAMQESGVPEQHSSTSSAADYLLKRQHVKKADWAVSNPQAVPGGWGFSHINTNNPDLDDTA AALKAIPFQRRPDAWNRGLAWLLSMQNKDGGFAAFEKDVDHPLIRNLPLESAAEAAVDPSTAD LTGRVLHLLGLKGRFTDNHPAVRRALRWLDHHQKADGSWYGRWGVCFIYGTWAALTGMKAV GVSANQTSVKKAISWLKSIQREDGSWGESCKSCEAKRFVPLHFGTVVQSSWALEALLQYERP DDPQIIKGIRFLIDEHESSRERLEYPIGIGLPNQFYIRYHSYPFVFSLLASSAFIKKAEMRETY >seq_ID 188 MRSELLQLQSADGSWRLCFDSGTMPDSYFIIILRMLGYSQDEALIRQIASRILSRQLPNGTWKIY PDEEDGNLDATAEAYFALLYSGFLTKLDPRMQLAKQFILSKGGLSKIRSLLTQAIFAAAGQASWP KSMRIPLEVFFSDNGIGIDLFSLSGHARVHIVPIIMLANAQFVQHSASMPDLSDLFAGSSKRFEN DSPWIAALATLIGSLSLSELLPFESPTPQEKAVQFLFDRLEPDGTLLTYTTATMFMILVLLMLGYS SSSPLIHRMVSGIHSVICANSHVQIASSEVWDTAMLVHALRKAGVNPTSTALENAGAYLRQRQQ TQLGDWAIRNPGTPAGGWGFSNVNTLYPDVDDTTAALRAIQPYSSRTPELQADWQRGLNWVL TMRNDNGGWPAFERQGSRLPITFFNFEGAKDIAVDPSTVDLTSRTLQFLGQELGMNAGNSWIE STLRWVLSQQESNGSWYGRWGITYVHGTSAALQGLTAVGIAEDHPAVKKGVDWLLQVQNED GGWGESCISDKVRRYVPLNFSTPSQTAWALDGLTAALPKPTPALERGVDALLQSLDRHDWTY TYPTGGALPGSVYAHYASNNYIWPLLALSNIWQKYS >seq_ID 60 MGTLQEKVRREQKKTITELRDRQNADGSWTFCFEGPIMINSFFILLLTSLDEGENEKELISSLAA GIHAKQQPDGTFINYPDETRGNLTATVQGYVGMLASGCFHRTEPHMKKAEQFIISHGGLRHVH FMTKWMLAANGLYPWPALYLPLSLMALPPTLPIHFYQFSSYARIHFAPMAVTLNQRFVLINRNIS SLHHLDPHMTKNPFTWLRSDAFEERDLTSILLHWKRVFHAPFAFQQLGLQTAKTYMLDRIEKD GTLYSYASATIYMVYSLLSLGVSRYSPIIRRAITGIKSLVTKCNGIPYLENSTSTVWDTALISYALQ KNGVTETDGSVTKAADFLLERQHTKIADWSVKNPNSVPGGWGFSNINTNNPDCDDTTAVLKAI PRNHSPAAWERGVSWLLSMQNNDGGFSAFEKNVNHPLIRLLPLESAEDAAVDPSTADLTGRV LHFLGEKVGFTEKHQHIQRAVKWLFEHQEQNGSWYGRWGVCYIYGTWAALTGMHACGVDRK HPGIQKALRWLKSIQNDDGSWGESCKSAEIKTYVPLHRGTIVQTAWALDALLTYENSEHPSVVK GMQYLTDSSSHSADSLAYPAGIGLPKQFYIRYHSYPYVFSLLAVGKYLDSIEKETANET >seq_ID 56 MQDFKTKVNVYMDELHMQMQHRQREDGAFVFCFEGSMMTNAFLIMLLKAVGDTDQALVHQL AEAIREKQNEDGSFSLYHDQAGHVTATVQGYCGMLVSGRYQQDEPHMEKAARYIRSKGGLKD VHFMTKWMLAVNGMHPWPYFYAPLSFLLIPTYFPLHFYHLSAYARIHFVPMMIALNKRYTSHEQ FPSLSHLDANMSKNPFDWFMAREERSTHHFLAYMRSYTALDSRFDFFGYEAAKRYMFDRLEK DGTLYSYLSASIFMVYALMSLGYSPGHHLILKAVKGMKQLVTDCGGKKYAENSTSTVWDTALV SYASQRAGRTQDDPVIKKSFTYLLNRQQMKKADWAIHNRHAAPGGFGFSDLNTNNPDCDDTQ IVLKAIPQTYAPVQWKRGFDWLLSMQNRDGGFSAFEKNQDHFLLRHLPLESAEDAAIDPSTPDI TGRVLHLIASEENDKSPLMQRQKDHCVKWLLDHQEKDGSWYGRWGVCYIYGTWAALTGLKA SGIPSSHPAVQKACRFLKTIQLEDGSFGESCKSSEVKRYVPLPFGTVVQTAWAAEALLQYVQP DDKSILKAISFLIQHQHSSKALHYPVGIGLPKQFYITYHSYPFVFPMMACSTFLEEMRRKNE >seq_ID 58 MKNRNKGAGCMQLVKSEIERLKQQLLSEQTPDGSWNHPFDTGCMTDIYMIVLLRTLEEEDEEE LIKELAKGILSRQGKDGAWRLFHDHHEGSLSLTIEAYYALLYSGYYEKNHPALVKARRVITKGGG LKKAGMYTKIMLALTGQYPWPLLFPVPMEVILLPRSFPLNMYDISVFGRSNLIPVILLGNKKFSRK TALSPDLGDLSVRDDDDPWPELRSAEWRSLTSFLAAGVKALVGIPRQIRAWSIEKAREYMQSH TEPDGTLYNYFSSTFYMIFALLALGGGPEEPAIRNAVAGLKRMTVKADGRTHIQYTTAAVWNTA LISHALQEAGVPPKENAIQKANQYLAGQQHRRFGDWIVHNTKAEPGGWGFSRFNTINPDVDDT TAALRSLYQPAREKPHYDDIWKKGLLWTLSMQNRDGGWPAFERNVDKKLLHLLPIQGAEFILT DPSTADLTGRTLEFLGKAGYADASLPPIKKAVKWLKKHQEPNGSWYGRWGICYIYGTWAAVTG MAAVGVTLEDKSMKKGIDWLLSIQNEDGGWGESCRSDMEKKYIPLKESTLTQTAWAVDALAAA GMADSTPSRKGAAFLVREGKRKDWTADYPMGQGMANFFYIHYHSYRCIWPLLALSHYIEKSEA PD >seq_ID 57 MQDFKTKVNEYIDELHMQLQRRQREDGAFVFCFEGPMMTNAFLIMLLKAVGDSDQALVHQLA EAIREKQNEDGSFSLYHDQAGHVTATVQGYCGMLVSGRYQQDEPHMEKAAHFIRSNGGLKDV HFMTKWMLAVNGMHPWPYFYAPLSFLLIPTYFPLHFYHLSAYARIHFVPMMIALNKRYTSHEQF PSLAHLDANMSKNPFDWFMAREERSTHHFLAYMRSYTALDSRLDFFGYEAAKRYMFDRLEKD GTLYSYLSASIFMVYALMSLGYSPGHHLILKAVKGMKQLVTDCGGRKYAENSTSNVWDTALVS YASQQAGRTQDDPVIKKSFTYLLNRQQMKKADWAIHNRHAAPGGFGFSDLNTNNPDCDDTQI VLKAVPQTYAPVQWKRGFDWLLSMQNQDGGFSAFEKNQNHFLLRHLPLESAEDAAIDPSTPDI AGRVLHLIALEENSMSPLMQRQKDHCVKWLLDHQEKNGSWFGRWGVCYIYGTWAALTGLKT AGISSSHSAVQKACRFLKTIQLEDGSFGESCKSAEVKRYVPLPFGTVVQTAWAAEALLQYVQP DDKVILKAISFLIQHQHSSEALHYPVGIGLPKQFYITYHSYPFVFPMMACSTFLEEMRRKNE >seq_ID 61 MGTLQEKVRRFQKKTITELRDRQNADGSWTFCFEGPIMTNSFFILLLTSLDEGENEKELISSLAA GIHAKQQPDGTFINYPDETRGNLTATVQGYVGMLASGCFHRTEPHMKKAEQFIISHGGLRHVH FMTKWMLAANGLYPWPALYLPLSLMALPPTLPIHFYQFSSYARIHFAPMAVTLNQRFVLINRNIS SLHHLDPHMTKNPFTWLRSDAFEERDLTSILLHWKRVFHAPFAFQQLGLQTAKTYMLDRIEKD GTLYSYASATIYMVYSLLSLGVSRYSPIIRRAITGIKSLVTKCNGIPYLENSTSTVWDTALISYALQ KNGVTETDGSVTKAADFLLERQHTKIADWSVKNPNSVPGGWGFSNINTNNPDCDDTTAVLKAI PRNHSPAAWERGVSWLLSMQNNDGGFSAFEKNVNHPLIRLLPLESAEDAAVDPSTADLTGRV LHFLGEKVGFTEKHQHIQRAVKWLFEHQEQNGSWYGRWGVCYIYGTWAALTGMHACGLTESI PVYKRLCVGSNPYKMMTEAGENPAKAPKSKHMYRFIEEPLYKRPGL >seq_ID 50 MAEAISYPRRVHIITTKFPVNFYDFSVFGRSNIAPILLLADSKFQIPKTTETPDISHLYVRELYWWS EDRGWNGFTKAINKGVNNLIGLPNELHTLGRKQAENYMLDRLEDDGTLLSYYSSTFFMIYALLS VGYTKDHKVIKKAARGLLSMNTTVKDTIHIQYTTAHIWNTSLISHALQTAGASPDDTMVMRANH YLLQRQHTKFGDWAIYQPNLGPGGWGFSHSNTFNPDVDDTTASLRSIQNSLHSHPNYQSSWY RGLSFTLGMQNQDGGFPAFEKGVDKTFLFILLPVQGAEFLLTDPSTPDLTGRTLEFLGESAHLY KDSGAIKRGVNWLIENQRRDGSWYGRWGICYIYGTWAALTGLQAVGVSKEHPSVQEGIDWLK SIQQDDGGWGESCESDSQKTYIPLSKSTVTQTAWAVDALIAYEKEETVEIKKGMEYLLENWNH EDWTMDYPMGQGMAKAFYIHYHSYRYVFPLLTMGHYMRKFM >seq_ID 199 MSETISCQRIQAAYQRSRAELLSLRNSTGHWTGELSTSALSTATAIMALEMIRRKRLPADLSLNT YIDNGIRWLAEHQNSDGGWGDTVKSFSNISTTMLCHAVFHATKSTEQYVSHVVNARQYIDRVG GVEAVVARYGKDKTFSVPILTHCALAGLVKWKTIPALPFELACLPARFYKTVRLFVVSYALPALIA IGQVRHHFCKPRNPITRLIRKLAVKRSLKKLISIQPSNGGFLEAAPLTSFVTMSLAGMGLTDHPV VQKGLQFLLDSVRPDGSWPIDTNLATWTTTLSVNALEGTLAEFEKTPIREWLLQQQYKELHPYT SAEPGGWAWTDLPGGVPDADDTPGAILALLNLQPDEPDTQQPADLQVALRNGVKWLLDLQNS NGGWPTFCRGWGALPFDQSAADISAHVIRALQAWLQTEPESAEAELRLRAERAVRKCFKYLAT VQRPDGSWLPLWFGNQHVENDENPVYGTARVLAAYAQGEQCGSIQAEQGILFLKSVQNLDG GWGGATSAPSSVEETALAVDTLLALGLEPADPVVAQGLNWLSGRVENGTYTETTPIGFYFAKL WYFEQLYPIIFTVSALHRAETVLKKSADDNLRLSLEEEDYPIMSVKEK >seq_ID 75 MDQDRLQRCYAIARDDLLAQRNGQGHWTGELSTSALSTATAVSALQLVVRHDPAQSERLMPLI EGGVRYLTEHQNPDGGWGDTDRSYSNIATTMLAVAALTIAERREALFEQLAFAENYIEAQGGIP GLRRRYGKDKTFAVPILTNYALAGLVDWREVSPLPFELACLPQKFYKLVKLPVVSYAIPALVAIG QARYFHRPPFNPLMRGLRGAAVKKSLAVLERMQPASGGYLEAAPLTSFVVMSLASIGNASHPV AQNGVQFLVDSVREDGSWPIDSNLANWVTTLSISALATGGDDIAELDCLPWVLANQYQETHPF TGADPGGWGWTDLSGSVPDADDTPGAMLAIAHFFHSPRADNETRRQIASAAISGARWLLDLQ NSDGGWPTFCAGWGTQPFDRSGSDLTAHAIRALHAWRSELGDLPVERAIERGLRYLQKQQR DDGSWLPLWFGNQDIHDDENPIYGTVKVLLAYRDLGKMSSETAQRGAAWLAARQNEDGGFG GGPSISTLCGGPGESSVEETALAIEALFAAENSNISAEIVPPAVGWLCQRVEEGSYVNCTPIGFY FSKLWYYEKLYPRVMTVTSLGAALQANASVPPAPETVTTSSDH >seq_ID 325 MATSDPSLAEAIQNTRAHLLSLRNARGHWEGHLSNSALSTATAIVALHLVDAPLHSARIAQGVR WLVLHQNKDGGWGDTTLSKSNLSTTLLCWSALSLCEPDRTEPIQHCEAWIKERTGSLEPEVIC RAVVARYGKDKTFSVPILMLCAIGGRLGPEKEAWSRVLALPFELAAMPREWFGAIGLPVVSYAL PALIAIGYARFYHAPPSLLNPLHALRKALWPRISPMLKLLQPSTGGYLEATPLTSFVTMALASAG EKFHPCVPEAVRFLEDSQRPDGSWPIDTNLATWGTTLSTKALTATSEGREALDIPALKSWLLEQ QYQEIHPFTNAAPGGWAWTDLPGGVPDADDTSGALVALWHLCEDEAERQALAPAVAKGVQW LMDLQNRDGGIPTFCRGWGTLPFDRSTPEITAHALHAWGLWQVVLPEELQQEVSLRIPRAIAFI ARPPSRGAPGFNHVPLWFGNEHAKEEENHVYGTAQIMNHLLSSGLNTPEIKVILETGHRNLLA WQQLDGGWSGSETGPASLEETAVSVAALALHTLHAGNRTRSSAEDAVAKGTQWLVQHTATG TTFPSAPIGLYFARLWYHEQLYPVIWTLGALHAVETLSAAALPLRARASAPPQHPGVVRTKPIHI APPSDP >seq_ID 135 MIPAERLRTAYRTARAALLAERVPEGHWVGELSTSALSTATAVMALHLVNPFTHRELIDAGRKW LAEHQNADGGWGDTVKSFSNISTTMLCRAAFKLAGEKEYPETVQRVEEYLSRNAGALPTARAA AIRARYGKDHTFSVPILMTCAVAKLVPWDEVPRLPFELACLPQSWYRFAKLPVVSYALPALIAIG QCIHHHRRSQNPIRNTVRRLARGLSLKVLRRIQPTSGGYLEATPLTSFVVMALSSIRRRRAAAE QQVIDEGVRFLVASVRPDGSWPIDTNLATWVTTLSVNALATAGDLEALDTKEQILAWLLKQQYK ERHPYTGADPGGWAWTDLPGGVPDCDDTPGALIALAHLDPKSDPQAVLSGLRWVLRLQNGD GGAPTFCRGWGTLPFDRSGADLTAHSVRSLASWYRVWGAGPPPIEHLRHRLKDLEFPLSGLF WDVARRNPRFVRYLKKQQRSDGSWLPLWFGNQHAPDDINPVYGTARVLAAYRDLELKDAPE CRRGIEFLLSVQNADGGWGGAKGCPSSVEETALAVEVLLDLADGDAVQKGVAWLAEAVESDR FRDASPIGFYFAKLWYFEKLYPIIFTVAALGRAVKITSPAPAAESA >seq_ID 115 METLSRSRLEAALAKATQALLTELNPAGHWSGELSSSALSTATAIVALGAVDREQQRELIAGGM RWLAQHQNADGGWGDTVKSRSNISTTALCWAAVSTSTEHAESAAKAEAWLTRAAGSMAQLV PAIEARYGKDRTFSVPILMHLAICGRVSWSQIPALPFELAALPHQLFGALQLPVVSYALPALIAIG QAIHHHAPPTNPLLNGLRKSARARTLEVLESIQPQNGGFLEATPLTSFVTMALASAGEAQHPVA RRGVSFLQASVQRDGSWAIDTNLATWVTTLSIKALAHQPGALSPERALTLREWLLGQQYVVEH PYTHAAPGGWAWTDLPGGVPDADDTPGALLALLHLGVVDAPTRQAGQIGVRWLLDLQNRDG GIPTFCRGWGALPFDRSSPDLTAHTLRAWTAWLPQLDESLKRRTLRAVTKAIHFLATHQRTDG SWLPLWFGNEHAPDDENPLYGTAKVVIALRELLNRDFTLPNGMLERALCWLVERQDISGGWS GAKNGPVSVEETALAVEALAGTGHVSATDRGAAWLTEQIEADTWREPAPIGFYFAKLWYYERL YPQIWTVGALGRVAALRVGESESDTPAGLHRATSET >seq_ID 208 MMAVVENSVSEVLDRRELRGTLDLLRGELLAQRTKDGHWTGELSASALSTATAISAMSAAVRS GKLAGADKAALLEQIQSGRRWLADQQNDDGGFGDTDRSHSNIATSYLVLAAWTLSDQVTGET TDANAISRLRNWIQLAGELDGLRRRYGKDKTFVVPILTNMAIAGLVPWKKVSALPFEAAVVPQS MYRFVGMPVVSYAVPALVAIGQVKFLEGGGCLPPWSLVRRAAIEPSMKVLRSMQPSSGGYLE ATPLTAFVVMSLSASGRADHEVTQNGLRFLRDSMLPDGSWPIDTNLANWATSLATTALTMDPD DDRSWSTNELIQWQRGCQYQERHPFTGADPGGWGWTDLTGSVPDADDTPGAIISLRMQATT RPDPLCDDYSRDWPASDSSGSVSANALDTWKACDRGVDWLLGLQNRDGGWPTFCRGWGKL PFDRSSNDLTAHALRAIACLPKRESAKRSRAVQRGLRFLRKNQQADGSWLPLWFGNQDRPEE DNPIYGTSRVLVDVSPALGHDAISRGLYYLINSQNSDGGWGGGESVRETFGLPEGFISSVEETA LAVEALVSWWGRIPGNEGGQAAENDIPDGSPWDASMRSALRAAILSGTRWLIDAVQRERHQV AWPIGFYFAKLWYYERLYPLVYTTAALGRVMQRDELLR >seq_ID 247 MEIQDEVDLLEPQESLTASADSAVDRALFWLLDAQYEDGYWAGILESNACMEAEWLLCFHVLG IANHPMSRGLVQGLLQRQRADGSWDVYYGARAGDINTTVEVYAALRCQGYAADHPDIKRARD WIQLQGGVKQVRVFTRFWLALIGEWPWEETPNLPPEILFFPRWFPFNIYHFAAWARATLVPLCI LSARRMVVPLNKKSCLQELFPEDRSAVVALGKKAGAWSTFFYHADRALKKYQRTFKRPPGRQ QAIKMCLEWILRRQDADGAWGGIQPPWIYSLMALKAEGYPVTHPVMAKGLAALDAHWSYERP GGARFVQACESPVWDTLLSSFALLDCGFSCTSSSELRKAVDWILDQQVLLPGDWQQKLPTVS PGGWAFERANVHYPDVDDTAVALIVLAKVRPDYPDTARVNLAIERGLNWLFAMQCRNGGWGA FDKDNDKDLLTKIPFSDFGETIDPASVDVTAHVLEALGLLGYRTTHPAVAKALEFIRSEQENDGC WFGRWGVNYIYGTAAVLPALASLNMNMNQEFIRRAANWILGKQNNDGGWGESCASYMDDTQ RGRGPSTASQTAWAMMSLLAVDGGTYAESLLRAEAYLKTTQTPEGTWDEPYYTGTGFPGYGI GRREIKRQRSLQQHAELSRGFMINYNLYRHYFPLMALGRLAALRGA >seq_ID 148 MTSPFKHPISHALTSFNGIVTEPEQSVEQKAGAKVHQFPASLWKSKPGKAKSPLDIAIEGCRDF FFREQLPKGYWWAELESNVTITAEYIMLFNFLSLVDHERQRKMSNYLLSKQTEEGFWTIYYGG PGDLSTTVEAYFALKLTGYPADHPAMVKARAFILEKGGVIKSRVFTKIFLALFGEFDWLGVPSMP VELNLLPNWAYVNVYEFSSWARATIIPLSIVMLKRPVHKLPPSQRVQELFVRPPRAIDYTFTKED GIFTWKNFFIGLDHMLKVYERSPVRPFKKRAMGKAEEWVLEHQEETGDWGGIQPAMLNAVLA LSALGYDNGHPAVAHGLKALENFCIESDEQIVLQSCISPVWDTALALKALVDAGVPSDHPSLVK GAQWLLEREVRRPGDWRVKSPDLEPGGWAFEFLNDWYPDVDDSGFVMIALKGVEVKDRKAM NAAVKRGIDWCLGMQSKNGGWGAFDKDNTRHILNKIPFADLEALIDPPTADLTGRMLELMGTF GYAKTYPAAQRALKFLKENQEPEGPWWGRWGVNYLYGTWSVLCGLAAIGEDLEQPYIKKAVN WIKSRQNMDGGWGETCESYHDPTLAGMGESTASQTGWALLGLMAAGEVHSATVVRGVQYLI STQSQDGTWDETQYTGTGFPKYFMIKYHIYRNCFPLMALGTYRTLTGGTA >seq_ID 149 MTSPFKHPISNALTSFNGNFAEPEQCVEQQTGAKVHHLPASIWKRKMGKAKSPLDVAIEGSRD FFFQEQLPKGYWWAELESNVTITAEYIMLFHFLGLVDRERQRKMSNYLLSKQTEEGFWPIYYG GPGDLSTTIEAYFALKLSGYPADHPALAKARAFILEQGGVVKSRVFTKIFLALFGEFEWQGVPS MPVELNLLPDWAYINIYEFSSWARATIVPLSVVMHSRPVRRVPPSARVQELFVRQPTAADYSFA KNDGIFTWENFFLGLDRVLKVYEKSPLRPFKNMALAKAEEWVLEHQEPTGDWGGIQPAMLNA VLALNVLGYQNDHPAVEQGLRALANFCIETEDQLVLQSCVSPVWDTALALKALLDAGVPPDHP SLVKGAQWLLDKEVTRPGDWRVKSPALEPGGWAFEFLNDWYPDVDDSGFVMIALKGIQVKDR KSMDAAIKRGINWCLGMQSKNGGWGAFDKDNTRHVLNKIPFADLEALIDPPTADLTGRMLELM GTFNYPITLPAAQRAIEFLKKNQEPEGPWWGRWGVNYLYGTWSVLCGLAAIGEDMDQPYIRKA VNWIKSRQNIDGGWGETCQSYHDRTLAGVGESTPSQTGWALLGLLAAGEMHSATVVRGVQY LISTQNSDGTWDEQQYTGTGFPKYFMIKYHIYRNCFPLMALGTYRTLTRTQP >seq_ID 216 MTDVLTRELSPNSTRDRVRSCVSSARQYLLSLQHEEGWWKGELDTNVTMEAEDLLLRQFLGIS DEQVTQETARWIRSCQREDGTWATFHGGPPDLSTTVEAYVALRLAGDAMDAAHLRKAREYIL DSGGIESTRVFTRIWLALFGEWPWSRLPVLPPEMMLLPDWFPLNIYDWASWARQTVVPLTIVG SLRPTRDLGFSVRELRTGIQRRDLESPLSWAGVFHGLDSVLHRLEKLPLKPLRKVALARAEQWI LDRQESDGGWGGIQPPWVYSILALHLRGYPLDHPVLRKALDGLDGFTIRHRTENGWIRKLEAC QSPVWDTALAMTALLDSGTPPNDPALVRAADWILRQEIRVSGDWRVRRPALEPSGWAFEFAN DHYPDTDDTAEVVLGLQRVRHPEPHRVNAAVERATAWLVGMQSSDGGWGAFDADNTRTLCE KLPFCDFGAVIDPPSADVTAHIVEMLAARGMADSESARRGVRWLLEHQEVDGSWFGRWGAN HVYGTGAVVPALVACGISPQHEAVRAAVQWLVAHQNADGGWGEDLRSYVDRTWVGRGTSTP SQTAWALLALLAAGERGEVVRRGVEWLMAAQRPDGGWDEPQYTGTGFPGDFYISYHMYRIV FPLTALGRYLGRGGDVGTG >seq_ID 229 MTATTDGSTGASLRPLAASASDTDITIPAAAAGVPEAAARATRRATDFLLAKQDAEGWWKGDL ETNVTMDAEDLLLRQFLGIQDEETTRAAALFIRGEQREDGTWATFYGGPGELSTTIEAYVALRL AGDSPEAPHMARAAEWIRSRGGIASARVFTRIWLALFGWWKWDDLPELPPELIYHDTWVPLNI YDFGCWARQTIVPLTIVSAKRPVRPAPFPLDELHTDPARPNPPRPLAPVASWDGAFQRIDKALH AYRKVAPRRLRRAAMNSAARWIIERQENDGCWGGIQPPAVYSVIALYLLGYDLEHPVMRAGLE SLDRFAVWREDGARMIEACQSPVWDTCLATIALADAGVPEDHPQLVKASDWMLGEQIVRPGD WSVKRPGLPPGGWAFEFHNDNYPDIDDTAEVVLALRRVRHHDPERVEKAIGRGVRWNLGMQ SKNGAWGAFDVDNTSAFPNRLPFCDFGEVIDPPSADVTAHVVEMLAVEGLAHDPRTRRGIQW LLDAQEADGSWFGRWGVNYVYGTGSVIPALTAAGLPTSHPAIRRAVRWLESVQNEDGGWGE DLRSYRYVREWSGRGASTASQTGWALMALLAAGERDSKAVERGVAWLAATQREDGSWDEP YFTGTGFPWDFSINYNLYRQVFPLTALGRYVHGEPFAKKSRAADAPAEAAPAEVKGS >seq_ID 113 MTDVIDKAVAATGPADPSQGAAATLQAAADHLLGLQDDAGWWKGELETNVTMDAEDLLLRQF LGIRTEEVTREAGDWIRSQQRADGTWANFFDGPADLSTTIEAYTALRMAGDAKDAEHMRAART YILDSGGIEASRVFTRIWLALFGEWQWSDLPVMPPELIYLPKWFPLNVYDWACWARQTVVPLTI VNALRPVRPLGFDLKELRTGRRAPAQRGLFSTLDRALHVYERKPLRSVRDAALRRSADWIIAR QEADGSWGGIQPPWVYSLMALNLLGYGVDHPVMRKGIEGLDRFTIRDERGRRLEACQSPVW DTVLAMTALRDAELPENHPALVKAADWVLGEEITNPGDWSVRRPRVAPGGWAFEFDNDGYPD VDDTAEVVLALNRVAHPDAPAAIRRGVDWLEGMACKDGGYGAFDADNTRTLALKLPFCDFGA VIDPPTADVTAHTLEAYAALGLANSRASQRALEWLVKAQERDGSWFGRWGANHVYGTGAVVP AMVAVGVDPEDEMIRRAVRWLEEHQNDDGGWGEDLRSYRDKSWIGRGVSTASQTAWALLAL LAAGEERGTAVEQGVRFLIRTQRADGTWDEDHYTGTGFPGDFYLNYHLYRLVFPISALGRYVR AVGAAGDGGDAGHAGHAGTVS >seq_ID 236 MTATTDGGGAITGGADPRHDSTAAPAAAAAGPSGGGTGLPEGVREAVDRATAELLARQDPAG WWKGDLQTNVTMDAEDLLLRQFLGIRDEAVTRAAALFIRGEQQGDGTWATFHGGPPELSATIE AYVALRLAGDPPDAPHMTRASAWIRAHGGIAAARVFTRIWLALFGWWSWDRLPELPPELVFLP PWVPLNIYDFGCWARQTIVPLTVVSALRPVRSAPFALDELHTDARDPVPAKPLPPLASWDGAF QRMDKALHLYRRVAPRRLRKAAMAAAGRWIVERQENDGCWGGIQPPAVYSVIALHLLGYDLG HPVMRAGLESLDRFAVWREDGARMVEACQSPVWDTCLAAIALADAGLPPDHPALVRAADWM LGEEIRRPGDWAVRRPGLAPGGWAFEFHNDNYPDIDDTAEVVLALRRIRHPQPGGVEAAIARG VSWTLGMQSKNGAWGAFDADNTSPFPNRLPFCDFGEVIDPPSADVTAHVVEMLAAEGRAADP RARRGIAWLLAEQEPDGPWFGRWGTNYVYGTGSVVPALTAAGIAPSHPAVRRAVRWLESVQ NEDGGWGEDQRSYRDRSWAGKGASTASQTAWALMALLSAGERDGDAVARGLAYLVETQRP DGTWDEPYFTGTGFPWDFSINYHLYRQVFPLTALGRYLHGEPFGPERRNVPPAGES >seq_ID 134 MSLTSDPSPATPATQPTSARPGSLSDRRSRSGGSAVAGPVLVTTRPVAPVAKSGAVTPTATSG AVTSTATSGPALLPDLATDLADPTGPLAGAASATVRAAGGAGTRTQQTGQLGSTELAGPQAD QVADRAAAVLGRARDHLLGLQSEAGWWKGELETNVTMDAEDLMLRQFLGILPPELAAETGRW IRSKQQDDGGWPTFHGGPSDLSTTFEAYVGLRLAGDLPDAPHMLAAASFVRAHGGLAATRVF TRIWMALFGEWPWDEVPVLPPELVLLPSWVPLNVYDFGCWARQTVVALTIVGHFRPVRSLGF SIDELRVAAVRPDRAPLVSWTGVFQRLDAGLRRYQRHPVKTLRELALRRATEWVLARQEADG GWGGIQPPWVYSIMALHLMGYSMDHPVLVAALDGLETFTVREQVREGDEVVTVRRLEACQSP VWDTALAVVALADAGLDARHPAMRKAGEWLVREEVTVPGDWRVRRPNLEPGGWAFEFANDI YPDVDDTAEVVLAVRRLLGSGWDDVDPTFAKQARASVERAVNWSVGMRSANGAWGAFDAD NVRELATKIPFCDFGEVIDPPSADVTAHMVEMLADLGRADHPVTQRAVRWLLDDQEPGGSWF GRWGVNHVYGTGAVVPALISAGVAADHPAIRSAVRWLVAHQHPDGGWGEDLRSYQDDAWV GRGEPTASQTAWALLALLAADPMNEAVGRGVRWLCDTQLPNGTWDEPYYTGTGFPWDFSIN YHLYRLVFPLTALGRYVTLTGRSAA >seq_ID 225 MTATTDGSTGAALPPRVTAASDTDTDIPVAAGVPDIAARAMRRATDFLLSRQSDQGWWKGDL ETNVTMDAEDLLLRQFLGIRDEGTTRAAALFIRGEQREDGTWATFHGGPGDLSATIEAYVALRL AGDPPDAPHLARASAWIREQGGIAASRVFTRIWLALFGWWKWEDLPELPPELIWFPAWVPLNI YDFGCWARQTIVPLTIVSAERPVRPAPFPLDELHTDPARPNPPRALAPVTGWDGAFQRLDKAL HVLRGAVPRRLRRAAMNTAARWIIERQENDGCWGGIQPPAVYSIIALHLLGYDLNHPVMRAGL ESLDRFAVWREDGARMIEACQSPVWDTCLATIALADAGLPADHPQLVKAADWMLGEQIVRPG DWSVRRPHLPPGGWAFEFHNDNYPDIDDTAEVVLALRRVAHHDPERVDNAIGRGVRWNLGM QSRNGAWGAFDVDNTSPFPNRLPFCDFGEVIDPPSADVTAHVVEMLAAEGLAHDPRTRRGVQ WLLAEQEPNGSWFGRWGVNYLYGTGSVVPALTAAGISGSHPAIRRAVAWLESVQNDDGGWG EDLRSYRDARGWSGRGASTASQTAWALMALLAAGERESRAVERGVEWLAATQHEDGSWDE PYFTGTGFPWDFSINYHLYRQVFPLTALGRYVNGEPLAGKPRAAGAATAREDTGQEQSLAEAK GS >seq_ID 223 MTATTDGSTGAANITGAPADDPTDTRTAANDVTDIARRAAERSVEHLLGRQDEQGWWKGDLA TNVTMDAEDLLLRQFLGIQDPATTRAAALFIRGEQLGDGTWNTFYGGPGDLSATIEAYVALRLA GDRPDEPHMARASGWIRDQGGIAAARVFTRIWLALFGWWKWDDLPELPPELMFFPKWVPLNI YDFGCWARQTIVPLTIVSAKRPVRPAPFALDELHTDPDHPNPPRKLAPPTSWDGLFQRLDKGL HLYHKVAPRPLRRIAMNVAARWIIERQENDGCWGGIQPPAVYSVIALHLLGYDLDHPVMKAGLA SLDRFAVHREDGARMIEACQSPVWDTCLATIALADAGLRPDHPALVKAADWMLAEEITRPGDW SVRKPELAPGGWAFEFHNDNYPDIDDTAEVVLALRRVRHPDPARLEAAIARGVRWNLGMQSR NGAWGAFDADNTSPFPNRLPFCDFGEVIDPPSADVTGHVVEMLAVEGLANHPRTREGIEWLLA EQEACGAWFGRWGVNYVYGTGSVVPALITAGLPAGHPAIRRAVDWLESVQNDDGGWGEDLR SYQEEKWIGHGESTASQTAWALLALLAAGRRDTASVTRGVTWLTEAQQADGSWDEPYFTGT GFPWDFSINYHLYRQVFPLTALGRYVHGDPFADRTDAAEGV >seq_ID 226 MTATTDGSTGAALPPRVTAASENDTDIPEAAGVPDIAAHAMRRATDFLLSRQDDQGWWKGDL ETNVTMDAEDLLLRQFLGIRDEDTTRAAALFIRGEQREDGTWATFHGGPGELSTTIEAYVALRL AGDPPEAPHMARASAWIRERGGIAAARVFTRIWLALFGWWKWEDLPELPPELIWFPSWVPLNI YDFGCWARQTIVPLTIVSAKRPVRPAPFPLDELHTDPRRPRPPRPHAPPNTWDGAFQRLDRAL HALRRAVPRRVRQAAMNAAARWIIERQENDGCWGGIQPPAVYSVIALHLLGYDLRHPVMRAGL ESLDRFAVWREDGARMIEACQSPVWDTCLAAIALADAGLPADHPSLVKAADWMLGEQIVRPG DWSVRRPHLPPGGWAFEFHNDNYPDIDDTAEVVLALRRVRHHDPERMDSAIGRGVRWSLGM QSKNGAWGAFDVDNTSPFPNRLPFCDFGEVIDPPSADVTAHVVEMLAVEGLAHDPRTRRGIQ WLLAEQEPDGSWFGRWGVNYLYGTGSVVPALAAAGIPGSHPAIRRAVAWLEKVQNDDGGWG EDLRSYRHVREWSGRGASTASQTAWALMALLAAGERDSGAVERGVAWLAATQREDGSWDE PYFTGTGFPWDFSINYHLYRQVFPLTALGRYVHGEPFSKKQTAARNGSAQPLAGVKGSR >seq_ID 219 MDPALSRAVDWLLEHQDPAGWWCGEFETNVTITAEHILLLRFLGLDPSPLRDAVTRYLLGQQR EDGSWALYYEGPADLSTSIEAYAALKVLGLDPTSEPMRRALQVIHDLGGVAQARVFTRIWLAMF GQYPWDGVPSMPPELIWLPPSAPFNLYDFACWARATITPLLIILARRPVRPLGCDLGELVLPGS EHLLTRVPGSGPFWWGDKVLKRYDHLVRHPGRDRACQRIVEWIIARQEADGSWGGIQSAWV MSLIALHLEGLPLDHPVMRAGLAGFDRVALEDERGWRLQASTSPVWDTAWAVLALRRAGLPR EHPRLALAVDWLLQEQIPGGGDWQVRTGTIPGGGWAFEFDNDHYPDIDDTAVVVLALLEAGH EDRVRNAVERAARWILAMRSTDGGWGAFDRDNAREVIHRLPIADFGTLIDPPSEDVTAHVLEM LARLSFPSTDPVVARGLEFLQQTQRPDGAWFGRWGVNYIYGTWCAVSALTAFADTDATARAM VPRAVAWLLDRQNADGGWGETCGSYEDPNLAGVGRSTPSQTAWAVLALQAAGLGQHPACR RGLDFLRERQVGGTWEEREHTGTGFPGDFFINYHLYRHVFPTMALAGAATGMDSPR >seq_ID 220 FLGIRDEATTRSAALFIRGEQREDGTWATFHGGPPDLSTTVEAYVALRLAGDSPDAPHMTRAA HWVRSQGGIAEARVFTRIWLALFGWWPWDRLPELPPELIFLPPWAPLNIYDFGCWARQTIVPL TVVSAKRPVRPAPFPLDELHTDPADPAPRARFAPLASWNGAFQRLDRALHAYRKVAPRALRRA AMATAGRWIVERQENDGCWGGIQPPAVYSMIALHLLGYDLGHPVMRAGLESLDRFTLTREDG SRMVEACQSPVWDTCLATIALADAGVPADHPQLVRAADWMLDEQIERPGDWSVRRPHLAPG GWAFEFHNDNYPDIDDTAEVVLALRRVRHPDTARMERAISLGVRWNLGMQSKNGAWGAFDV DNTSSLPNRLPFCDFGEVVDPPSADVTAHVVEMLAAEGLAADPRTRRAVDWLLAEQEPSGAW FGRWGVNYLYGTGSAVPALVDAGLPTTHPAIRRAVAWLESVQNDDGGWGEDLRSYREQGRM ARGASTASQTGWALMALLAAGERESRAARRGVTFLAETQHEDGSWEEPYYTGTGFPWDFSIN YHLYRQVFPLTALGRYTRGAAPEGA >seq_ID 125 MQTQNRVTSTQKVELSNLTQAIIASQNYILSRQYPEGYWWGELESNITLTAETVLLHKIWKTDKT RPFHKVETYLRRQQNEQGGWELFYGDGGELSTSVEAYMALRLLGVTPEDPALIRAKDFILSKG GISKTRIFTKFHLALIGCYDWKGIPSIPPWIMLFPDNFPFTIYEMSSWARESTVPLLIVFDKKPIFEI EPAFNLDELYAEGVENVKYALPRNHNWSDIFLGLDKLFKWTEKNNLVPFHKKSLQAAEKWMLN HQQESGDWGGIMPPMVNSLIAFKVLNYDVADPSVQRGFEAIDRFSIEEEDTYRVQACVSPVWD TAWVIRALVDSGLKPDHPSLVKAGEWLLDKQILEYGDWAIKNKQGKPGGWAFEFINRFYPDLD DSAVVVMALNGIKLPDENRKKAAINRCLEWMATMQCKPGGWAAFDVDNDQAWINEIPYGDLK AMIDPNTADVTARVLEMVGSCGLKMDENRVQKALFYLEKEQESDGSWFGRWGVNYIYGTSGV LSALAVIAPNTHKPQMEKAVNWLISCQNEDGGWGETCWSYNDSSLKGTGISTASQTAWAIIGL LDAGEALETLATDAIKRGIDYLLATQTPDGTWEEAEFTGTGFPCHFYIRYHLYRHYFPLIALGRY WKIGLKTPSVIPLN >seq_ID 228 MLARRATDRAVRHLLSRQDEQGWWKGDLETNVTMDAEDLMLRHFLGIQNPDVLDAAGRYIRS QQAADGTWATFHGGPPELSATVEAYVALRLAGDPPDAPHMAAASAWVRNNGGVASSRVFTRI WLALFGWWRWEDLPELPPEIIYFPPWLPLNLYDFGCWARQTIVPLTVVSAKRPVRPAPFSLDE LHADPRRPNPPRPAAPLASWDGAFQRLDRALHLYRKVALRPLRRAALRSCARWIVERQENDG CWGGIQPPAVYSVIALHLLGYDLDHPVMRAGLESLDRFAVWREDGSRMIEACQSPVWDTCLA VIALADAGLAPDHPALVKSADWMLAEEIDRPGDWSVKRPRLAPGGWAFEFDNDNYPDIDDTAE VILALRRVDHPRPERIAAAVRRGVRWTLGMQSRNGAWGAFDVDNTSPLPNRLPFCDFGEVIDP PSADVTAHVVEMLAHEGGARDPRTRRAVGWLLAEQEPSGAWFGRWGTNYVYGTGSVVPALV AAGLPATHPAIRRAVRWLESVQNEDGGWGEDQRSYPDPEWIGHGASTASQTAWALLALLAAG ERESKAVERGVGWLAATQDQDGSWDEPYFTGTGFPWDFSINYHLYRLVFPLTALGRYVSGEA TGARPRRT >seq_ID 241 MTATTDGSTGALPPRADAASEHDIETPEAAGVREAAVRAARRATDFLLSRQDAQGWWKGDLE TNVTMDAEDLMLRQFLGVLDEKTAQAAALFIRGEQREDGTWASFYGGPGELSTTIEAYVALRL AGDAPDSPHLAKASAWIREQGGIAAARVFTRIWLALFGWWKWEDLPELPPELIWFPKWVPLNI YDFGCWARQTIVPLTIVSAKRPVRPAPFPLDELHTDPARPNPPRPLAPAFSWDGAFQRMDKGL HALRKVAPRGLRRAMANAAARWIIERQENDGCWGGIQPPAVYSIIALHLLGYDLQHPVMREGL ASLDRFAVWREDGARMVEACQSPVWDTCLAAIALVDAGLPADHPQLVKAADWMLGEEIVRPG DWSVRRPGLPPGGWAFEFHNDNYPDIDDTAEVILALRRITHHDPVRVDKAVGRGVRWTLGMQ SKNGAWAAFDVDNTSPFPNRLPFCDFGEVIDPPSADVTAHVIEMLAVEGLAHDPRTRRGIEWL LAEQEPDGSWFGRWGVNYVYGTGSVVPALVAAGLPGAHPAIRRAVSWLESVQNDDGGWGE DLRSYKYVKEWSGRGASTASQTAWALMALLAAGERDSKAVERGVEWLAATQREDGSWDEPY FTGTGFPWDFSINYHLYRQVFPLTALGRYVHGEPFADRLKGS >seq_ID 238 MHEGEAMTATTDGSTGAATPPATTASAPLHLSPEARETHEATARATRRAVDFLLARQSDEGW WKGDLATNVTMDAEDLLLRQFLGIRDEATTRAAALFIRGEQQEDGTWNTFYGGPGDLSATIEG YVALRLAGDSPEAPHMRKASAFVRAQGGVARARVFTRIWLALFGWWKWEDLPEMPPELMFF PKWAPLNIYDFGCWARQTIVPLTVVCAQRPVRPAPFALEELHTDPADPDPAQPAPPVVSWDNV FHKLDKLLHGYRRIAPRRVREAAMRAAATWIVERQENDGCWGGIQPPAVYSIMALNLLGYDLD HPVLRAGLASLDRFAVWREDGARMIEACQSPVWDTCLATVALADAGVPADHPQMIKAADWML AEQIVRPGDWVVRRPDLPPGGWAFEFHNDNYPDIDDTAEVVLALRRVAHPDATRVDKAVRRA VDWNVGMQSKNGAWGAFDADNTSPFPNRLPFSDFGEVIDPPSADVTAHVVEMLAEEGLAHH PRTRRGIEWLLKNQEGNGSWFGRWGVNYVYGTGAVVPALVAAGLPASHPAIRRSVSWLGQV QNEDGGWGEDLRSYQDSAWHGRGHSTASQTAWALLALLAAGERETEQVRRGIAYLVETQTE DGTWDEPWFTGTGFPWDFTINYHLYRQVFPVTALGRYLNGTGPGEN >seq_ID 237 MRRRRSPRGPGAGPEADYGPARASAPDRLRGDAARGDAARRVQDATARAIRNLLGRQDPAG WWKGDLETNVTMDAEDLLLRQFLGIRDEAVTQAAALFIRREQREDGTWATFHGGPPELSATIE AYVALRLAGDAPDAPHMATASAWIRAHGGLAAARVFTRIWLALFGWWDWENLPELPPELVLLP PWVPLNIYDFGCWARQTIVPLTVVSAMRPVRPAPFALDELHTDARVPVPPRRMAPPTTWNGA FQWMDRALHVYRRFAPRRLREAAMASAGRWIIERQENDGCWGGIQPPAVYSVIALHLLGYDL GHPVMRAGLESLDRFAVWREDGSRMIEACQSPVWDTCLAAIALADAGVRPDHPALVKAADW MLGEEIVRTGDWAVRRPGLAPGGWAFEFHNDTYPDIDDTAEVVLALRRIRHPDPARVEAAIAR GVSWNLGMQSRGGAWGAFDADNTSPFPNRLPFCDFGEVIDPPSADVTAHVVEMLAAEGRAA DPRTRRGIAWLLAEQEPEGPWFGRWGTNYVYGTGSVVPALTAAGLSPGHPAIRRAVLWLESV QNPDGGWGEDQRSYQDRAWAGKGESTPSQTAWALMALLSAGERDAKTVERGIAYLVETQLA DGGWDEPHFTGTGFPWDFSINYHLYRHVFPLTALGRYLYGEPFGHDGRHIGAHLGDRTGVPA EGV >seq_ID 239 MDFLLDRQSDEGWWKGDLATNVTMDAEDLLLRQFLGIRDEATTQAAALFIRGEQQEDGTWNT FYGGPGDLSATIEGYVALRLAGDSPEAPHMRKASAFVRARGGVARARVFTRIWLALFGWWKW EDLPEMPPELMFFPKWAPLNIYDFGCWARQTIVPLTVVCAQRPVRPAPFALEELHTDPADPNP AQPAPPVASWDNVFHKLDKMLHGYRKVAPRRVREAAMRAAATWIVERQENDGCWGGIQPPA VYSIIALHLLGYDLDHPVLRAGLESLDRFAVWREDGARMIEACQSPVWDTCLATVALADAGVPA DHPQMIRAADWMLAEQIVRPGDWVVRRPDLPPGGWAFEFHNDNYPDIDDTAEVVLALRRVAH PDATRVDKAVRRAVDWNAGMQSKNGAWGAFDADNTSPFPNRLPFSDFGEVIDPPSADVTAH VVEMLAEEGLAHHPRTRRGIEWLLENQEANGSWFGRWGVNYVYGTGAVVPALVAAGIPAAHP AIRRSVSWLGQVQNEDGGWGEDLRSYQDTAWHGRGHSTASQTAWALLALLAAGERDSEQV RRGIAYLVETQTEDGTWDEPWFTGTGFPWDFTINYHLYRQVFPVTALGR >seq_ID 235 MTQTVPRTAASAPAARTAADTVAAAVQFLRREQDRAGWWKGELATNVTMDAEDLLLRHFLGI LTPQIAEESARWIRSQQRADGTWANFPDGPADLSTTVEAWVALRLAGDPADAPWLATAAEWI REHGGIEATRVFTRIWLAMVGQWSWDDLPSLPPELIFLPSWFPLNVYDFACWARQTIVPLTIVG TLRPARKLPFDVAELRTGKRPPKPRAPWTWDGVFQNLDTALHAYAKLPLNPVRKLALKQAAE WILARQEADGSWGGIQPPWVYSILALHLLGYSLDHPALKAGIAGLDGFTIREKTDQGWVRRLEA CQSPVWDTALAMTALLDAGVSPGDESLVRAAEWMLGEEIRVPGDWAVRRPSLKPGGFAFEFA NDGYPDTDDTAEVVLALRRMGKPDHLRIREAVDRSVAWLEGMQSSDGGWGAFDADNTQVLT TRLPFCDFGAVIDPPSADVTAHVVEMLAAEGKADTRECRRGIRWLWDNQEADGSWFGRWGA NYVYGTGAVVPALVAAGVPGTDPRIRRAVRWLAEHQNDDGGWGEDLRSYDDRSWAGRGDS TPSQTAWALLALLAAGERESTVVARGVEWLCERQRPDGGWDEDKHTGTGFPGDFYLSYHLY RVVFPLSALGRYVRGGS >seq_ID 159 MSGQSNFTGGKKMTPAEGSSSPAPALLEKAAPSIELDERSDPLSRTLARAVSWLVAAQDGAG HWVAPLEADATIPSEYVFLHEVLGRPLDPVRRDKIVRAILSVQGKEGAWPLFHDGDPDISATVK AYQALKLCGFDPSHPALVRAREWVLSQGGAGKVNVFTRIALAIFGQYSWTKIPALPAEMVLLPS WFPFSIYSVSYWSRTVIVPLLFIYHHKPLVRLSPERGISELFDPARPDGESFAPSPDFFSLRNLFL LLDKVLQVWNRHPPGFLRKKALSFAMEWMVPRLKGEGGLGAIYPAMANSAVALSLEGYELDH PLMQRVLASIDDLLIEGEKEVLVQPCVSPVWDTALAMGALIEAGISPDSPTVDRAMEWFCAREV RTRGDWAIRAPDCEPGGWAFQFENDYYPDVDDTAMVLMGMAKILPARPDLAARMEGVFRRA TLWVMAMQGTDGGWGAFDRDNDLLFLNHIPFADHGALLDPSTADLTGRVLELLGALGYGPDF PPAARAIRYLRREQEEDGSWFGRWGVNYIYGTWSVVAGLKSIGVPMSEPWVMRSMEFLLAR QNPDGGWGEDCLSYASRDFAGRGASTPSQTAWALIALLHGGHAGHMAVRQGVDYLIQQMTP EGTWNEELFTGTGFPRVFYLRYHMYRHYFPLWALALYRNMTERGRALGHERVDFWKTAPYA PIARSV >seq_ID 232 MTATTDGSTGALPPRAPSASDTDHGTPVAAGVQEAALHAVGRATDFLLSRQDAQGWWKGDL ETNVTMDAEDLLLRQFLGIRDDATTRAAALFIRGEQRPDGTWATFYGGPPDLSATVEAYVALRL AGDDPAAPHMAKASAWIRARGGIAAARVFTRIWLALFGWWKWDDLPEMPPEIVYFPTWMPLNI YDFGCWARQTIVPLTVVSAKRPVRPAPFPLDELHTDPGRPNPPRPLDRLGSWEGAFQRLDRA LHGYHKVALKRLRRAAMNRAARWIVERQENDGCWGGIQPPAVYSVIALHLLGYDLGHPVMRA GLESLDRFAVWREDGARMIEACQSPVWDTCLATIALADAGLPPDHPQLVKAADWMLGEEIVRP GDWSVKRPQLPPGGWAFEFHNDNYPDIDDTAEVVLALRRVRHPDPERVERAVRRGVRWTLG MQSGNGAWAAFDADNTSPFPNRLPFCDFGEVIDPPSADVTAHVVEMLAAEGLSHDPRTRRGI EWLLAEQEPGGAWFGRWGVNYVYGTGSVVPALVTAGLPAAHPAIRRAVAWLETVQNDDGG WGEDLRSYPDPAEWGGKGASTASQTAWALLALLAAGERDGKATERGVAWLARTQREDGSW DEPYFTGTGFPWDFSINYHLYRQVFPLTALGRYVHGEPAVLKPGTR >seq_ID 224 MTATTDGSTGAANLRAAAASDPTESTSAAPDMMAVARHAAERSVEHLLGRQDEQGWWKGDL ATNVTMDAEDLLLRQFLGIQDPETVKAAARFIRGEQLGDGTWNTFYEGPPDLSATVEAYVALRL AGDRPDDPHMIRAAGWVREQGGIAESRVFTRIWLALFGWWKWDDLPELPPELMFFPKWVPL NIYDFGCWARQTIVPLTIVSAKRPVRPAPFALDELHTDPACPNPSRPTAPAASWDGVFQRLDKA LHLYHKVAPRRLRRIAMNEAARWIIERQENDGCWGGIQPPAVYSVIALHLLGYDLDHPVMRAGL ESLDRFAVWREDGARMIEACQSPVWDTCLATIALADAGVSPDHPALVRAADWMLGEEIVRPG DWAVRKPGLAPGGWAFEFHNVNYPDIDDTAEVALALRRVRHPDPARVDAAIERGVRWNLGM QSRNGAWGAFDADNTSPFPNRLPFCDFGEVIDPPSADVTGHVVEMLAVEGRAHDPRTRRGV EWLLAEQEASGAWFGRWGVNYIYGTGSVVPALIAAGLPAAHPSVRRAVDWLRSVQNDDGGW GEDLRSYREEKWIGHGSSTASQTGWALLALLAAGERETRSVERGVAWLAATQQADGSWDEP HFTGTGFPWDFSINYHLYRQVFPLTALGRYVYGDPFATATAIGAGTGKGA >seq_ID 243 MSISALQTDRLSQTLTQSVVAAQQHLLSIQNPEGYWWANLESNASITAEVVLLHKIWGTLDSQP LAKLENYLRAQQKTHGGWELYWNDGGELSTSVEAYMGLRLLGVPASDPALVKAKQFILHRGG VSKTRIFTKFHLALIGCYRWQGLPSLPAWVMQLESPFPFSIYELSSWARGSTVPLLIVFDKKPVY PLQPSPTLDELFTESAENVRWELEEKGDWSDAFLWLDKAFKLAESVDLVPFREESIRKAEKWV LERQEPSGDWGGIIPAMLNSMLALRALGYSVSDPVVRRGFQAIDNFMVESETECWAQPCISPV WDTGLAVRSLTDSGLSPNHPALVKAGEWLLDKQILSYGDWSVKNPQGQPGGWAFEFENSFY PDVDDTAVVAMALQDITLPNEPLKRRAIARAVRWIATMQCKTGGWAAFDINNDQDWLNDIPYG DLRAMIDPSTADITGRVLEMHGRFAADLDLANSYAADLSPYRLSRGLNYLIKEQELDGSWFGR WGVNYIYGTGQALSALALIAPERCRIQIERGIAWFVSVQNADGGWGETCESYKDKSLKGKGIST ASQTAWALLGLLDVSFCLDPAAKIAVDRGIQYLVSTQSEGTWQEESFTGTGFPQHFYLRYRLY CHYFPLMALGRYQRVINSSAGI >seq_ID 197 MTSGTFGAKRVDLLAAFEHSAPAEKTRETCVGLQTAIARTRQYLLDQQHSEGFFVAELEGDTIL ESEYILLLAFLNEGQSPDAQAAARYLLTKQNTDGSWSNFPGGPIDVSCAVKAYLALRITGHAAD EPALIRAREAILQAGGVERVNSFTRFYLAMLGLIPYSLCPAVPPEVVLLPDWFPINLSQMSAWSR TIVVPLSLLWAFQPAVELNDADGHQITIEELYASPEKQLPRFIRGVNHESNSNGWMNWSRFFFR VDQCLKSIESYGIKPLRSRAVRKCVQWILDRQEMSDGLGAIFPPIVWTLIGLKCAGFDDQHPMV QKQRDELNRLMLREQDALRLQPCLSPVWDTAISIIALRESGVEPDHPALSKARNWLLSKEVRHA GDWSKAHPETPVSGWYFEFNNEFYPDVDDTAMVLIALASTLPEEATPLAISHGVLPVQTGWSA ESTSRVQALKQLENHRPVLEAMGRGVQWLKALQSKDGGWGAFDSDINKELLTKVPFADHNAM LDETNADISARVLEAYAAVGISFNDPSVQRALEFIWNDQEDDHAWYGRWGVNYIYGTWQVLV GLTAIGISAHDPRLVRAAGWLKSKQQACGGWGETPATYDNPTLRGQGTPTASQTAWAVLGLIA AGEQNSIECQRGVEFLLKTQKHNGTWDEEEFTGTGFPRVFYLRYHYYPLYFPLMALGRFARA GGRVNFAG >seq_ID 158 MTTNAAATSARSGEDAIRQVSGQQLETAIASARNSLLALQRPDGHFVFELEADATIPAEYVLMR HYLAERVDAVLEEKIARYLRRIQSDDGGWPLFRDGASNISASVKAYYALKMIGDAPNAPHMQKA RAWILAQGGASHSNVFTRNLLALFGAIPWSGVPVMPVEIMLLPKWFPFHIDKISYWARTVLIPLT VLNALKPVARNPKGVGIAELFVTPPDQVRNWPKGPHQKFPWSQVFGGIDRVLRLFEPAFPKSL RKKSIDKAVAFATERLNGEDGLGGIFPAMVNALLVYDALGYPHDHPDYVTARGSIEKLLVIKDDE AYCQPCLSPVWDTALAVHALMESGVAQADQNVDRALAWLKPLQVLDTVGDWAASRPGVRPG GWAFQYANAYYPDVDDTAVVVMAMDRAAGGDAAKRDHYRESMARGREWVAGVQSKNGGW GAFDADNTYEYLNQIPFSDHGALLDPPTADVSARCVSMLAQLGERRETSPVLDKAMRYLESTQ EKDGSWYGRWGMNYIYGTWSVLCALNAAGVAPSAPSMRKAADWLLSIQNSDGGWGEDGES YSLDYKGYEPAPSTASQTAWALMGLMAAGEVDHPAVQRGVAYLAAKQGSDGFWGEERFTAT GFPRVFYLRYHGYSKFFPLWALARYRNLNAANSKSVLVGM >seq_ID 77 MAADGSALSESRLSSEALDRAVLSAHTALSQAQQDDGHWVYELEADATIPAEYILLEHFMDRID DALEQKIAIYLRRIQSEEHGGWPLYHNGKFDLSATVKAYFALKAVGDDINAPHMQRAREAILDH GGAERSNVFTRSQLALFGEVPWRATPVMPVELMLLPAKAFFSVWNMSYWSRTVIAPLLVLAAL RPVAANPRQVHVRELFVTPPEKVQDWIRGPYRSAWGYVFKGLDSVLRPVVPFIPEKTHKKAIQ AALDFIEPRLNGKDGLGAIYPAMANVVMMYRAMGVPDEDPRAKTAWEAVQALIVEKDDEAYC QPCVSPIWDTGLSGHAMIEAASGPNGIAPEKTVAELKKASAWLRSKQILNVKGDWAVRNPNLA PGGWAFQYGNDYYPDVDDTAVVGMLLHREGDPTNAEAIERARTWIVGMQSTDGGWGAFDID NNKDVLNHIPFADHGALLDPPTADVTARCISFLAQLRNPEDEPVIQRGLEYLRKEQEKDGSWFG RWGTNYIYGTWSALCALNAAGVSHDDPAVVKAVEWLRSVQRADGGWGEGCESYEGGPHGT YGESLPSQTAWAVLGLMAAGRRDDPAVTRGIAWLADQQDANGEWHEDPYNAVGFPKVFYLR YHGYKQFFPLMALARYRNLESSNTRRVSFGF >seq_ID 6 MTVSTSSAFHHSSLSDDVEPIIQKATRALLEKQHQDGHWVFELEADATIPAEYILLKHYLGEPED LEIEAKIGRYLRRIQGEHGGWSLFYGGDLDLSATVKAYFALKMIGDSPDAPHMLRARNEILARG GAMRANVFTRIQLALFGAMSWEHVPQMPVELMLMPEWFPVHINKMAYWARTVLVPLLVLQAL KPVARNRRGILVDELFVPDVLPTLQESGDPIWRRFFSALDKVLHKVEPYWPKNMRAKAIHSCV HFVTERLNGEDGLGAIYPAIANSVMMYDALGYPENHPERAIARRAVEKLMVLDGTEDQGDKEV YCQPCLSPIWDTALVAHAMLEVGGDEAEKSAISALSWLKPQQILDVKGDWAWRRPDLRPGGW AFQYRNDYYPDVDDTAVVTMAMDRAAKLSDLHDDFEESKARAMEWTIGMQSDNGGWGAFDA NNSYTYLNNIPFADHGALLDPPTVDVSARCVSMMAQAGISITDPKMKAAVDYLLKEQEEDGSW FGRWGVNYIYGTWSALCALNVAALPHDHLAIQKAVAWLKNIQNEDGGWGENCDSYALDYSGY EPMDSTASQTAWALLGLMAVGEANSEAVTKGINWLAQNQDEEGLWKEDYYSGGGFPRVFYL RYHGYSKYFPLWALARYRNLKKANQPIVHYGM >seq_ID 89 MNDLTNSSAPGARPDDATPSAAGPTPAEAAGGAVAPSRAVQPADTQTAATGAAGAAAAVGAT PAELAATAPASSGTPAGASAAPAPSGTPSVDAPAELASAAPAPSGATPAATATAATAPAPARA ASIDAPALAAADLDAAITRATDALLAAQQADGHWIYELEADSTIPAEYVLLVHYLGETPNLELERK IARYLRRVQLPGGGWPLFTDGAPDVSASVKAYFALKMIGDDANAEHMVRARNAIHAMGGAEM SNVFTRIQLALFGVVPWFAVPMMPVEIMLLPQWFPFHLSKVSYWARTVTVPLLVLSAKRPLARN PRGVRVDELFVAPPVNAGLLPRAGHQSPAWFACFRLLDGLLRLTDGLFPRYTRERAIRQALQF VDERLNGEDGLGAIYPAMANSVMMYAALGYPEDHPNRATARRAIEKLLVIHDDEAYCQPCLSP VWDTSLAAHALLETGEPRAEAAAIRGLDWLRPLQILDVRGDWISRRPDVRPGGWAFQYANPH YPDVDDTAVVTLAMDRVAKLAQTDAYRDAIARAREWVVGMQSSDGGWGAFEPENTHQYLNSI PFSDHGALLDPPTADVSGRCLSMLAQLGETAANSAPARRALDYLLAEQGADGSWYGRWGMN YIYGTWSALGALNAAGLPFDDPRVKRAAQWLLSIQNPDGGWGEDGDSYKLDYRGYERAASTA SQTAWALLGLMAAGEVEHPAVARGIAWLAAQQREHGLWDEARFTATGFPRVFYLRYHGYRKF FPLWALARYRNLRRTGTRRVTVGM >seq_ID 201 MLPYNQNSYKEALHGGHAAHNPPTLEEAIKRSQEFLLAHQHPEGFWWGDLECNVTSASHTLIL YKILGIADRYPLHKFEKYLRRMQCSHGGWEMSFGDGGYLSATIEAYICLRLLNVPQSDPALQRA LKNILARGGVTKARVFTKVCLALLGGFDWAALPSLPPWLMLFPAWFPWNIYEAASWARGCVVP LIVLLEKKPVFQVKPEVSFDELYVEGRAHACKALPFSAHDWVSNIFVAADRAFKLMERFGAVPF RQWSIKEAKKWVLDRQEEMGDFIGYNPPMLYFAVCLKLWGYEVTDPLLQRALLAHKKLTVETE DECWLQSSQSPVWDTALVIPALVESGLPPDHPALQKAGQWLLEKQILKHGDWALKTGGGRMQ DDIGGGWAFQFVNSWYPDVDDSAAVVIALNCIKMPDEDVKNGAIARCLKWIAFMQGRNGGWA AFDRDSNQRWMDATPFSDIEAMLDVSTADVTARVLEMVGLMRLKHAAQPANNSLGKAHRHIS TESIARGVDYLTKEQEKEGCWWGRWGVNYIYGTRGALMGLSQVAAKTHKKEIARGAAWLVKV QNKKNEKKQGAQDGGWGEACFSYDDPATKGQNSRSTASQTGWAMQGLLAAGEVLGRKYEM EAVEEGVQFLLDTQRKDGSWSEAEFTGGGFPKHYYLKYHYFAQHFPLSALARYRARLLQLSR PKNQA >seq_ID 183 MDGSQRISDMSQQPEGIAVSDEISSAYSVSSLNQDEINVDELENKLTQARSAMLSLQKPDGHW CFPLEADCTIPAEYILMMHFMDEIDVILENKIARFIREKQDLTHGGWPLYYGGAFDISCTIKSYYA LKLVGDSPDAAHMVRAREAILERGGAAKANVFTRLLLAMYEQIPWSGVPVVPTELMLLPSWFP FHISKVSYWSRTVMIPLSILCTIKARAINPRNVIDIRELFIVPPEQEKNYFPQADTWLKRAFMLVER VLSRVEPKLPQAIRQYSIRKAENWTLERLNGECGIGAIFPAMVNAHESLALLGYAYDHPSRVQC RNALRGLLVDEGERAWCQPCTSPVWDTVLTCLALQEDPAADQGPVLKALDWLVDQQVLDEP GDWRDKRPDLLGGGWAFQYANPHYPDLDDTAAVAWALDQSDAQRYQKPLDRAANWLAGMQ SRNGGFAAFDIDNTYHYLNEIPFADHGALIDPPTSDVTARCVGLLGKYGKHQREVWRGISFLLR EQEKNGSWFGRWGTNYIYGTWSVLEAFQLANFDMQHTSVRRAVKWLESVQRVDGGWGETN DSYLDIQLAGQFPQTSTTFQTAWAVLGLMAAGEVNSKSVRRGINYLLHNQADDHLWEDPWFT APGFPRVFYLRYHGYSKFFPIWALVRYRALTKERVS >seq_ID 102 MNDLSQTQPLDAVLPEAADAASNLAEAAVVANAPAVADALATATPSPMQTAGASPLDVSITRA TDAILAAQQPDGHWIYELEADATIPAEYVLLVHYLGETPNLELEQKIARYLRRIQLPNGGWPLFT DGALDISASVKAYFALKMIGDPVDAEHMVRARDAILAHGGAEHANVFTRILLALFGVVSWRAVP MMPVEIMLLPMWFPFHLSKVSYWARTVIVPLLVLNAKRPLARNPRKVRIDELFRGAPVNTGMN ERAPHQHAGWFGFFRCVDTVLRAVDGLLPKASRERAIRAAVAFVDERLNGEDGLGAIFPAMAN SVMMYDVLGYPADHPNRAIARKSLDKLLVIKEDEAYCQPCLSPVWDTSLVAHALLETREARAE QAAERGLAWLRPLQILDVRGDWISRRPNVRPGGWAFQYNNAHYPDVDDTAVVAMAMHRSAA LTKSDVDREAIARAREWVVGMQSSEGGWGAFEPENTQYYLNNIPFSDHAALLDPPTADVSGR CLSMFAQIGELPQNSEPAQRAFDYMLQEQESDGSWYGRWGLNYIYGTWTALCSLNAAGMSH DDPRMRRAVQWLVSIQNEDGGWGEGGESYKLDYRGYERAPSTASQTAWALLGLMAAGEVD HDAVARGIDYLQREQREHGLWDETRFTATGFPRVFYLRYHGYRKFFPLWALARFRHLKRNGL TRVTVGM >seq_ID 90 MIRPMKNSDLPLPSLLDAAILRGRDALAQRQSADGSWCFELESDATITAEYILMMHFMGKIDEA RQARMARYLRGIQRLATHGAWDLYVDGAPDVSCSVKAYFALKAAGDSEDAPHMARARETILKL GGAAKSNVFTRILLATFGQVPWRATPFMPVEFVLFPKWVPISMYKVAYWARTTMVPLLVLCSL KARAKNPRNVSIRELFVTAPEAERHYFARGGFVRNLFLGIDRALRPLDALIPKALRRRAIRHAEA WCAERMNGEDGMGGIFPPIVYSYQMMDVLGYPEDHPLRRDCENALDKLLVERPDGSVYCQP CLSPVWDTAWSTMALEQARAVPDPRDAPPVSDAQLQRCIAASYEWLAGKQVTQVRGDWVEN APAATPAGGWAFQYENPYYPDIDDSAVVAAMLHRRGRLLARSTGTDPYAQVVARGLDWMRG LQSRNGGFGAFDADCDRLYLNLIPFADHGALLDPPTEDVSGRVLLCLGVTGRDEDKPALARAIE YVKRMQRADGCWWGRWGTNYIYGTWSVLAGLALAGENPSQPYIARAIAWLRACQNADGGW GETNDSYLDPALAGTNGGESASNVTAWALLAQMAFGDWQSESVQRGIRYLLSVQQADGFWW HRSHNAPGFPRIYYLKYHGYTAYFPLWALARYRRLSQAGAARDVTDGAALAAS >seq_ID 67 MREAAVSKVETLQRPKTRDVSLDDVERGVQSATRALTEMTQADGHICFELEADATIPSEYILFH QFRGTEPRPGLEAKGNYLRRTQSKVHGGWALVHDGPFDMSASVKAYFALKMIGDDIEAPHM RAVRKAILQRGGAANANVFTRILLALYGEVPWVAVPVMPVEVMHLPKWFPFHLDKVSYWARCT MVPLFVIQAKKPRAKNPRGVGVAELFVTPPDSVRTWPGSPHATWPWTPIFGGIDRVLQKTQDH FPKVPRQRAIDKAVAWVSERLNGEDGLGAIFPAMVNSVLMYEVLGYPPEHPQVKIALEAIEKLV AEKEDEAYVQPCLSPVWDTALNSHAMLEAGGHQAEANARAGLDWLKPLQILDIKGDWAETKP NVRPGGWAFQYANPHYPDLDDTAVVVMAMDRAQRQHGLVSGMPDYSESIARAREWVEGLQ SADGGWAAFDADNNHHYLNHIPFSDHGALLDPPTADVTARVVSMLSQLGETRATSRALDRGV TYLLNDQEKDGSWYGRWGMNFIYGTWSVLCALNAAGVDPQSPEIRKAVAWLIRIQNPDGGWG EDASSYKLNPEFEPGYSTASQTAWALLALMAAGEVDDPAVARGVNYLVRTQGQDGLWSEER YTATGFPRVFYLRYHGYPKFFPLWAMARFRNLKRGNSRQVQFGM >seq_ID 133 MTTTDETALAAGTPKAAFAPAPRGAADDLVARTVAVEAPPSPAPASDDTLARAVAHLKSLQDE AGWWKGDLETNTTMDSEDLMLRHWLGIWNPEQAERTARFIRSKQYADGSWPIYHAGPGDLN ATVESYVALRMVGDSPQDPHMRAAAAWARARGGVPATRIFTRIWLALFGWWRWEDLPVLPP ELIFVPAKMPLSIYKFASWGRQTIVAIMVLMAHRPAGTPPFPIAELFPPPATKKKAAAQRKAQKK AGHAGGPTAWRDSSIDDMFTEPAPGTDTLRQPAALAIGPARPAPAKGRRGKGQPAAPDVMG RAKDGGGPGLPLPARLVSRVGFRTRRALRQAALDHVNWNLLFGGIDRFLHVYHRHPIRPVRSL ALGLAERWIVVRQEADGCFGGIQPPTVYSIMALRVLGYPMDHPVMTAALRSLDEYSVTLPDGA RMQEACQSPVWDTCLATIALADAGVPRDDPSLVRAADWMLAEEVRERRGDWSVPIPDVPTG GWSFEFDNDTYPDVDDSAEVMLALMRVAHPRPEKVVAATYRGLQWVFGMQCADGGWGAFD VDNAGELVYKIPFADFGMLTDPPSADVTAHVVELLGELGLGDDPRTKRGVEWLLHSQEADGS WYGRWGVNHLYGTGGVVPALRAAGLPASHPAIQRAADWLVAKQNPDGGWGESCYSYDEMS TAGVGVSTASQTAWALLALIAAGRVGDGVTGEAAARGVAWLAETQTAEGTWDEDYFTGTGFA GYFYINYHLYRLVWPVMALGRYQAALAGKGH >seq_ID 7 MNPVVHNLTRPHRSAEPRPSALQRSIAAAQAALLQHQAADGHWCFEFEADCTIPAEYILMMHY MDERDAALEAKMAAYLRRKQENHGGWSLYHGGHFDMSASVKAYFALKLAGDDPEAAHMRRA RSAILAHGGAERANVFTRITLALFGQVPWRAVPFIPVEILLFPRWFPMHIYKVASWSRTVMVPLF ILCSLKPQAKNPLGVHIRELFTRPPEDIDDYFAHALQGWVSRIFLWFDRLGRALESWIPQALRRR AIARAEAWFIERLNGEDGLNGIFPAMVNAHEALALLGYAAEHPYRQQTRAALTKLVVERAGEAY CQPCVSPVWDTCLALHALLEADGDVSEAARRSMQWLLDRQITDAPGDWRERRPHLAGGGWA FQYANPYYPDLDDTAAVAWALARARRPEDRPAVERAANWLAGMQSRNGGFGAYDVDNTYYY LNEIPFADHKALLDPPTADVSGRVLAFLAILDREQDAPVRARLIQYLLREQEPSGAWFGRWGTN YIYGTWSVLMGMAELRDPGAEVRDAMARAAHWLRSVQQDDGGWGESNDSYADPGLAGLGQ ESTAAQTAWACLALMAAGDSDSESLRRGIQWLQRHQEQPGDWQDPYFNAPGFPRVFYLTYH GYKIYFPLWALARYRNITERHCA >seq_ID 190 MALSNGEIREEIQRLSEELIQRQEPDGSWRFCFENGITIDACTIILLRTLNVDKEELIRQLHDRIVA AQQPEGCWRWYHDDKEGHLSATVEAYYALLCSGYSRPEDEPIQRAKRYILDRGGIGQARSLF TKAILAATGQRKWPASLSLIPIEILLLPESLPLNFYDFSGYSRVHLVPLLIMAERNFRTRSVRTPDL SELFLDARNGEEDPLTLTPESREPLKLIQSGLAHLVGTPRRIRQAAVNRAEQYMLDRIEGDGTL YTYASCTVLMVFALLALGYEPQHPVIQRAVEGLSQMKFTVDSTGQGGTRYVTIQNSPSTVWDT ALISYALQEAGVSSSHPAIQRAADYLRNRQHRRPGDWQIHNPGIVPGGWGFSETNTFVPDVDD TTAALRALSALHGSEPAVLGAWNRGLNWVWSMQNNDGGWPAFEKNTNKEMLTWLAIEGAKS AATDPSEADLTGRTLEYLGNFAKLSVRQDWVARGADWLLSHQEADGSWYGRWGICYIYGTW AALTGLMAVGMPADHPGIAKAANWLIRIQNADGGWGESCRSDQVRRYVPLHASTPSQTAWAL DALIAVHDRRAPEIERGVARLIALLHEDDWPSTYPTGAGLPGYFYVHYHSYRYIWPLLALSHYV NKYGDSSP >seq_ID 45 MSGVLLYDKVREEIERRTTALQTMQRQDGTWSFCFEGALLTDCHMIFLLKLLGRNDEIEPFVKR LASLQTNEGTWKLYEDENGGNLSATIQAYAALLASEKYSKEDINMRRAEMFIKEHGGVSRAHF MTKFLLAIHGEYEFPTLFHFPTPILFLQDDSPLSIFELSSSARIHLIPMMICMNKRFRVEKKLLPNL NHIAGEGGQWFREERSPLFQSFVGDVKKVIAYPLSLHHKGYEEVERFIGERIDENGTLYSYASA TFYMIYALLALGHSIQSPIIEKAVIGLKSYIWKMDRGSHLQNSPSTVWDTALLSYSLQEANVMKE NKMIQKATEYLLQRQQTKRMDWSVHAPSIMAGGWGFSDVNTTIPDVDDTTAALRALARSRGS SRVDSAWERGVEWLKGLQNNDGGWGAFERGVTSRILANLPIENASDMITDPSTPDITGRVLEF FGTYAPNELPEEQKKKAVKWLMDVQELNGSWYGKWGICYIYGTWAAMTGLRALGVPSSHPSL KKAASWLEHLQYEDGGWGESCQSSVEKKFISLPFSTPSQTAWALDALISYYDQETPIIRKGISYL LAQPTMNEKYPTGTGLPGGFYIRYHSYGHIYPLLALAHYIKKYKK >seq_ID 53 MSGVLLYDKVHEEIERRTTALQTMQRQDGTWQFCFEGALLTDCHMIFLLKLLGRNDEIEPFVKR LVSLQTNEGTWKLYEDEKGGNLSATIQAYAALLASERYSKEAMNMRRAEMFIKEHGGVSRAHF MTKFLLAIHGEYEFPALFHFPTPILFLQDDSPLSIFGLSSSARIHLIPMMICMNKRFRVEKKLLPNL NHIAGGGGQWFREERSPLFQSFLGDVKKVISYPLSLHHKGYEEVERFMKERIDENGTLYSYAS ATFYMIYALLALGHSIQSPIIEKAVTGLKSYIWKMDRGSHLQNSPSTVWDTALLSYSLQEAKVTN ENKMIQRATEYLLQKQQTKKVDWSVHASSLVAGGWGFSDVNTTIPDIDDTTAALRALARSRGN DRVDDAWGRGVEWVKGLQNNDGGWGAFERGVTSKLLSNLPIENASDMITDPSTPDITGRVLE LFGTYAPNELLEEQKKKAIKWLMDVQEQNGSWYGKWGICYIYGTWATMTGLRALGVPSTHPA LKKAASWLEHLQHEDGGWGESCQSSVEKKFISLPFSTPSQTAWALDALISYYDQETPIIRKGIS YLLAQSTMNEKYPTGTGLPGGFYIRYHSYGHIYPLLALAHYVKKYRK >seq_ID 44 MSGVLLYDKVHEEIERRTTALQTMQRQDGTWQFCFEGALLTDCHMIFLLKLLGRNDEIEPFVKR LASLQTNEGTWKLYEDEKGGNLSATIQAYAALLASEKYSKEDMNMRRAEMFIKEHGGVSRAHF MTKFLLAIHGEYEFPALFHFPTPILFLQDDSPLSIFGLSSSARIHLIPMMICMNKRFRVEKKLLPNL NHIAGGGGQWFREERSPLFQSLLGDVKKVISYPLSLHHKGYEEVERFMKERIDENGTLYSYAS ATFYMIYALLALGHSIQSPIIEKAVTGLKSYIWKMDRGSHLQNSPSTVWDTALLSYSLQEAKVTN ENKMIQRATEYLLQKQQTKKVDWSVHASSLVAGGWGFSDVNTTIPDIDDTTAALRALARSRGN DRVDDAWGRGVEWVKGLQNNDGGWGAFERGVTSKLLSNLPIENASDMITDPSTPDITGRVLE LFGTYAPNELLEEQKKKAIKWLMDVQEQNGSWYGKWGICYIYGTWATMTGLRALGVPSTHPS LKKAASWLEHLQHEDGGWGESCQSSVEKKFISLPFSTPSQTAWALDALISYYDQETPIIRKGITY LLAQSTMNEKYPTGTGLPGGFYIRYHSYGHIYPLLALAHYVKKYRK >seq_ID 64 MSNLLLYEKVHEEIARRTTALQTMQRQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LASLQTNEGTWKLYEDEAGGNLSATIQSYAALLASEKYTKEDANMKRAEMFINERGGVARAHF MTKFLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPNL NHIAGGGGEWFREDRSPVFQTLLSDVKKIITYPLSLHHKGYEEVERFMKERIDENGTLYSYATA SFYMIYALLALGHSIQSPIIEKAITGITSYIWKMERGSHLQNSPSTIWDTALLSYALQEAQVPKASK VIHNASAYLLRKQQTKKVDWSVHAPDLFPGGWGFSDVNTTIPDIDDTTAALRALARSRGNENV DNAWKRAVNWVKGLQNNDGGWGAFEKGVTSRILANLPIENASDMITDPSTPDITGRVLEFFGT YTQNELPEKQKQSAINWLMNVQEENGSWYGKWGICYIYGTWAVMTGLRSFGIPSSNPSLKRA ALWLEHIQHEDGGWGESCQSSVEKRFVTLPFSTPSQTAWALDALISYYDKETPVIRKGISYLLS NSYINEKYPTGTGLPGGFYIRYHSYAHIYPLLTLAHYAKKYKK >seq_ID 68 MLLYEKVHEEIARRTTALQTMQRQDGTWRFCFEGAPLTDCHMIFLLKLLGKDKEIEPFVKRLAS LQTNEGTWKLYEDEVGGNLSATIQSYAALLASEKYTKEDVNMKRAEMFINEHGGVARAHFMTK FLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPNLNHI AGGGGEWFREDRSPVFQTLVSDVKKIITYPLSLHHKGYEEVERFMKERIDENGTLYSYATASFY MIYALLALGHSIQSPIIQKAITGITSYIWKMERGSHLQNSPSTVWDTALLSYALQEAQVPKASKVI HNASAYLLRKQQTKKVDWSVHAPDLFPGGWGFSDVNTTIPDIDDTTAALRALARSRGNENVDT AWKRAVNWVKGLQNNDGGWGAFEKGVTSRILANLPIENASDMITDPSTPDITGRVLEFFGTYT QNELPEKQKQSAINWLMNVQEENGSWYGKWGICYIYGTWAVLTGLRSLGIPSSDPSVKRAAL WLEHIQHEDGGWGESCQSSVEKRFVTLPFSTPSQTAWALDALISYYDKETPVIRKGISYLLSNS YINEKYPTGTGLPGGFYIRYHSYAHIYPLLTLAHYAKKYRK >seq_ID 41 MSNLLLYEKVHEEIARRTTALQTMQRQDGTWQFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LASLQTNEGTWKLYEDEMGGNLSATIQSYAALLASEKYTKEDANMKRAEMFINERGGVARAHF MTKFLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPNL NHIAGGGGEWFREDRSPVFQTLVSDVKKIITYPLSLHHKGYEEVERFMKERIDENGTLYSYATA SFYMIYALLALGHSIQSPIIQKAITGITSYIWKMERGSHLQNSPSTVWDTALLSYVLQEAQVPKAS KVIHNASAYLLRKQQTKKVDWSVHAPDLFPGGWGFSDVNTTIPDIDDTTAALRALARSRGNEN VDTAWKRAVNWVKGLQNNDGGWGTFEKGVTSRILANLPIENASDMITDPSTPDITGRVLEFFG TYTQNELPEKQKQSAINWLMNVQEENGSWYGKWGICYIYGTWAVLTGLRSLGIPSSDPSVKRA ALWLEHIQHEDGGWGESCQSSVEKRFVTLPFSTPSQTAWALDALISYYDKETPVIRKGISYLLS NSYINEKYPTGTGLPGGFYIRYHSYAHIYPLLTLAHYAKKYRK >seq_ID 66 MSNLLLYEKVHEEIARRTTALQTMQRQDGTWQFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LASLQTNEGTWKLYEDEMGGNLSATIQSYAALLASEKYTKEDANMKRAENFIKERGGVARAHF MTKFLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPNL NHIAGGGGEWFREDRSPVFQTLASDVKKIITYPLSLHHKGYEEVERFMKERIDENGTLYSYATA SFYMIYALLALGHSIQSPIIEKAIMGITSYIWKMERGSHLQNSPSTIWDTALLSYALQEAQVPKAS KVIQNASAYLLRKQQTKKVDWSVHAPDLFPGGWGFSDVNTTIPDIDDTTAVLRALARSRGNEN VDNAWKRAVNWVKGLQNNDGGWGAFEKGVTSRILANLPIENASDMITDPSTPDITGRVLEFFG TYGQNELPEKQKQSAINWLTNAQEENGSWYGKWGICYIYGTWAVLTGLRSLGIPSSDPSLKRA ALWLEHIQHEDGGWGESCHSSVEKRFVTLPFSTPSQTAWALDALISYYDKETPVIRKGISYLLS NPYINEKYPTGTGLPGGFYICYHSYAHIYPLLTLAHYAKKYRK >seq_ID 138 MVADERSALIDALKRSQSVDGSWRFPFETGISTDAYMIILLRTLGIHDEPLIQALVERIESRQDAN GAWKLFADEGDGNVTATVEAYYALLYSGYRKKTDSHMQKAKARILEVGGLERVHLFTKVMLAL TGQHSWPRRFPLPLVFFLLPPSFPLNMYDLSVYGRANMVPLLVVAERRYSRKTDNSPDLSDLA ASRNDWRLPDTEALWSYVKRSLTGLPAWLHRAAEQRAVRYMLEHIEPDGTLYSYFSSTFLLIFA LLALGYPKDDPHIARAVRGLRSLRTEIDGHTHMQYTTASVWNTALASYALQEAGVPPTDRTIEK ANRYLLSRQHIRYGDWAVHNPYGVPGGWGFSDVNTMNPDVDDTTAALRAIRRAAAKETAFRH AWDRANRWLFSMQNDDGGFAAFEKNVGKRFWRYLPIEGAEFLLMDPSTADLTGRTLEYFGTF AGLTKDHSAIARAIDWLLDHQEADGSWYGRWGICYVYGTWAAVTGLSAVGVPIDHPAMQKAV RWLLSIQNDDGGWGESCKSDGAKTYVPLGASTPVHTAWALDALIAAAERPTPEMKAGVRALV RMLHHPDWTASYPVGQGMAGAFYIHYHGYRYIFPLLALAHYEQKFGPFVD >seq_ID 69 MLLYEKVHEEIARRTTALQTMQRQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKRLAS LQTNEGTNKLYEDEVGGNLSATIQSYAALLASEKYTKEDANMKRAEMFINERGGVARAHFMTK FLLAVHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPNLNHI AGGGGEWFREDRSPVFQTLLSEVKKIITYPLSLHHKGYEAVERFMKERIDENGTLYSYATASFY MIYALLALGHSIQSPIIQKAITGITSYIWKMERGSHLQNSPSTVWDTALLSYALQEAQVPKASKGI QNASAYLLRKQQTKKVDWSVHAPDLFPGGWGFSDVNTTIPDIDDTTAVLRALARSRGNENVD NSWKRAVNWVKGLQNNDGGWGAFEKGVTSRILANLPIENASDMIPDPSTPDITGRVLEFFGTY AQNELPEKQKQSAINWLMNIQEENGSWYGKWGICYIYGTWAVLTGLRSLGIPSSDPSLKRAAL WLEHIQHEDGGWGESCQSSVEKRFVTLPFSTPSQTAWALDALISYYEKETPVIRKGISYLLSNP YVNEKYPTGTGLPGGFYIRYHSYTHIYPLLTLAHYAKKYRK >seq_ID 67 MSNLLLYEKVHEEIARRTTALQTMQRQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASEKYTKEDANMKRAEMFINERGGVARAHF MTKFLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPNL NHIAGGGGEWFREDRSPVFQTLLSEVKKIITYPLSLHHKGYEEVERFMKERIDENGTLYSYATA SFYMIYALLALGHSIQSPIIQKAITGIASYIWKMERGSHLQNSPSTVWDTALLSYALQEAQVPKAS KVIQNASAYLLRKQQTKKVDWSVHAPNLFPGGWGFSDVNTMIPDIDDTTAVLRALARSRGDEN VDNAWKRAVNWVKGLQNNDGGWGAFEKGVTSRILANLPIENASDMITDPSTPDITGRVLEFFG TYAQNELPEKQKQSAINWLMNVQEENGSWYGKWGICYNGTWAVLTGLRSLGIPSSDPSLKRA ALWLEHIQHEDGGWGESCQSSVEKRFVTLPFSTPSQTAWALDALISYYEKETPIIRKGISYLLSN PYVNEKYPTGTGLPGGFYIRYHSYAHIYPLLTLAHYTKKYRK >seq_ID 35 MSNLLLYEKAHEEIVRRATALQTMQWQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVER VASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASKKYTKEDANMKRAENFIQERGGVARAHF MTKFLLAIHGEYEYPSLFHLPTPIMFLQDDAPFSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPN LNHIAGGGGEWFREDRSPVFQTLLSDVKQIISYPLSLHHKGYEEIERFMKERIDENGTLYSYATA SFYMIYALLALGHSLQSSMIQKAIAGITSYIWKMERGNHLQNSPSTVWDTALLSYALQEAQVSK DNKMIQNATAYLLKKQHTKKADWSVHAPALTPGGWGFSDVNTTIPDIDDTTAVLRALARSRGN KNIDNAWKKGGNWIKGLQNNDGGWGAFEKGVTSKLLAKLPIENASDMITDPSTPDITGRVLEFF GTYAQNELPEKQIQRAINWLMNVQEENGSWYGKWGICYIYGTWAVMTGLRSLGIPSSNPSLKR AASWLEHIQHEDGGWGESCHSSVEKRFVTLPFSTPSQTAWALDALISYYDTETPAIRKGVSYLL LNPYVNERYPTGTGLPGAFYIRYHSYAHIYPLLTLAHYLKKYRK >seq_ID 43 MNALLLYEKVHEEIARRTTALQTMQRQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEVEPFVK RLASLQTNEGTWKLYDDEMGGNLSATIQSYAALLASKKYTKEDANMKRAEMFITERGGVARAH FMTKFLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLP NLNHIAGGGGEWFREDQSPMFQTLLGNVKQIISYPLSLHHKGNEEVERFMKERIDENGTLYSY ASASFYMIYALLALGHSIQSPMIQKAITGITSYIWKMERGNHLQNSPSTVWDTALLSYALQEARV SKESKMIQNASAYLLKKQHKKKADWSVHAPVLIPGGWGFSDVNTTVPDVDDTTAVLRALAQSR GNGNVDDAWKKGTNWIKGLQNNDGGWGAFEKGVTSKLLANLPIENASDMITDPSTPDITGRVL EFFGTYTQNELPEKQKQSAINWLMNEQEENGSWYGKWGICYIYGTWAVMTGLRALGITSAHP SLKRATLWLEHIQHEDGGWGESCQSSVEKRFATLPFSTPSQTAWALDALISYYDKETPAIRKGI SYLLANPYVNEKYPTGTALPGGFYIHYHSYAHIYPLLTLAHYAKKYKK >seq_ID 33 MNIVIRISKGWVSNLLLYEKVHEEIARRTTALQTMQRQDGTWQFCFEGAPLTDCHMIFLLKLLG RDKEIEPFVKRLASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASKKYTKEDANMKRAEMFIN ERGGVARAHFMTKFLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMVCLNKR FQVGKKLLPNLNHIAGGGGEWFREDRSPMFQTLLSDVKQIISYPLSLHHKGYEEVERFMKERID ENGTLYSYATASFYMIYALLALGHSLQSSMIQKAIAGITSYIWKMEKGNHLQNSPSTVWDTALLS YTLQEAHASKDNKMIQHAAAYVLKKQHTKKADWSVHAPGLIPGGWGFSDVNTTIPDVDDTTAV LRALARSRGNENVDNAWKKGVNWVKGLQNNDGGWGAFEKGVTSNLLANLPIENASDMITDPS TPDITGRVLELFGTYAQNELPEKQKQSAINWLMNVQEENGSWYGKWGICYIYGTWAVMTGLR SLGIPSSNPSMKRAALWLEHIQHEDGGWGESCQSSVEKRFITLPFSTPSQTAWALDALISYHDE ETPAIRKGISYLLANPYVNEKYPTGTGLPGGFYIHYHSYAYIYPLLTLAHYIKKYRK >seq_ID 36 MSNLLLYEKVHEEIARRATALQTMQRQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASQKYTKEDANMKRAENFIKERGGVARAHF MTKFLLAIHGEYEYPSLFHVPTPIMFLQNDSPLSIFELSSSARIHLIPMMVCLNKRFRVGKKLLPN LNHIAGGGGEWFREDRSPLFQTLLSDVKQIISYPLSLHHKGYEEVERFMKERIDENGTLYSYAT ASFYMIYALLALGHSLQSSMIQKAIAGITSYIWKMERGSHLQNSPSTVWDTALLSYALQEAQVPK DHKMIQQTITYLLKKQHTKKADWSVHAPALTPGGWGFSDVNTTVPDVDDTTAVLRVLARSREN EKVNNAWQKGIDWVKGLQNNDGGWGAFEKGVTSKLLANLPIENASDMITDPSTPDITGRVLEL FGTYTQNELPEKQKQSAINWLMNAQEENGSWYGKWGICYIYGTWAVMTGLRSLGIPSNNPSL KRAALWLEHIQHEDGGWGESCQSSMEKRFITLPFSTPSQTAWALDALISYYDTETPAIRKGISY LLANPYVNEKYPTGTGLPGGFYIRYHSYAQIYPLLTLAHYTKKYRK >seq_ID 42 MSNLLLYEKVHEEIARRTTALQTMQRQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASEKYTKEDANMKRAEMFINERGGVARAHF MTKFLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPNL NHIAGGGGEWFREDRSPVFQTLVSDVKKIITYPLSLHHKGYEEVERFMKERIDENGTLYSYATA SFYMIYALLALGHSIQSPIIEKAIMGITSYIWKVERGSHLQNSPSTIWDTALLSYALQEAQVPKASK VIQNASAYLLRKQQTKKVDWSVHAPDLFPGGWGFSDVNTTIPDIDDTTAVLRALARSRGNEHV DNAWKRAVNWVKGLQNNDGGWGAFEKGVTSRILANLPIENASDMITDPSTPDITGRVLEFFGT YTQNELPEKQKQSAINWLMNVQEENGSWYGKWGICYIYGTWAVLTGLRSLGIPSSDSSLKRAV LWLEHIQHEDGGWGESCQSSVEKRFVTLPFSTPSQTAWALDALISYYDKETPVIRKGISYLLSN PYINEKYPTGTGLPGGFYIRYHSYAHIYPLLTLAHYAKKYRK >seq_ID 65 MSNLLLYEKVYEEIARRTTALQTMQRQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASEKYTKEDANMKRAEMFINERGGVARAHF MTKFLLAIHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLPNL NHIAGGGGEWFREDRSPVFQTLVSDVKKIITYPLSLHHKGYEEVERFMKGRIDENGTLYSYATA SFYMIYALLALGHSIQSPIIEKAIMGITSYIWKMERGSHLQNSPSTIWDTALLSYALQEAQVPKVS KVIQNASAYLLRKQQTKKVDWSVHAPDLFPGGWGFSDVNTTIPDIDDTTAVLRALARSRGNEN VDNAWKRAVNWVKGLQNNDGGWGAFEKGVTSRILANLPIENASDMITDPSTPDITGRVLEFFG TYTQNELPEKQKQSAINWLMNVQEENGSWYGKWGICYIYGTWAVLTGLRSLGIPSSDSSLKRA VLWLEHIQHEDGGWGESCQSSVEKRFVTLPFSTPSQTAWALDALISYYDKETPVIRKGISYLLS NPYINEKYPTGTGLPGGFYIRYHSYAHIYPLLTLAHYAKKYRK >seq_ID 39 MNNLLLYEKVHEEIARRATALQTMQQQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASKKYTKEDANMKRAENFIKERGGVARAHF MTKFLLAIHGEYEYPSLFHLPTPIMFLQNDSHLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPSL NHIAGGGGEWFREDRSPLFQTLVSDVKQIISYPLSLHHKGYEEVERFMKERIDENGTLYSYATA SFYMIYALLALGHSLQSTMIQKAITGITSYIWKMESGNHLQNSPSTVWDTALLSYALQEAHVPKD NKMIQHAATYLLKKQHTQKADWSVHAPALTPGGWGFSDVNTTIPDVDDTTAVLRALARSRGNE KVDNAWPKGINWVKGLQNNDGGWGAFEKGVTSNILANLPIENASDMITDPSTPDITGRVLEFF GKYAQNELPEKQKQSAINWLMNVQEENGSWYGKWGICYIYGTWAVMTGLRSLGIPSSNPSMK RAALWLEHIQHEDGGWGESCHSSVEKRFVTLPFSTPSQTAWALDALISYYDKETSIIRKGISYLL ANPYVNEKYPTGTGLPGGFYIRYHSYAHIYPLLTLAHYIKKYRK >seq_ID 63 MSNLLLYEKAHEEIARRATALQTMQREDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LATLQTNEGTWKLYEDEVGGNLSATIQSYAALLASGKYTKEDANMKRAENFIKERGGVARAHF MTKFLLAIHGEYEYPSLFHVPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPN LNHIAGGGGEWFREERSPLFQTLLSDVKQIISYPLSLHHKGYEEVERFMKERIDENGTLYSYAT ASFYMIYALLALGHSLQSSMIQKAIAGITSYIWKMESGNHVQNSPSTVWDTALLSYALQEAHVP KDNKMLQNATAYLLKKQHTKKADWSVHAPALTPGGWGFSDVNTTVPDVDDTTAVLRVLARSK GNEKLDHAWQKGINWVKGLQNNDGGWGAFEKGVTSRILANLPIENASDMITDPSTPDITGRVL EFFGTYAQNELPEKQKQSAINWLMNAQEENGSWYGKWGICYIYGTWAVMTGLRSFGIPSSNP SLKRAALWLEHIQHKDGGWGESCHSSVEKRFVTLPFSTPSQTAWALDALISYYDTETPVIRKGI SYLLANPYVNEKYPTGTGLPGGFYIRYHSYAHIYPLLTLTHYIKNIENKPRDISRFIFLGSRSLLKRI RLCFPYFSVDWRF >seq_ID 37 MSNLLLYEKAHEEIARRATALQTMQREDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASGKYTKEDANMKRAENFIKERGGVARAHF MTKFLLAIHGEYEYPSLFHVPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLPN LNHIAGGGGEWFREERSPLFQTLLSDVKQIISYPLSLHHKGYEEVERFMKERIDENGTLYSYAT ASFYMIYALLALGHSLQSSMIQKAIAGITSYIWKMESGNHVQNSPSTVWDTALLSYALQEAHVP KDNKMLQNATAYLLKKQHTKKADWSVHAPALTPGGWGFSDVNTTVPDVDDTTAVLRVLARSK GNEKLDHAWQKGINWVKGLQNNDGGWGAFEKGVTSRILANLPIENASDMITDPSTPDITGRVL EFFGTYAQNELPEKQKQSAINWLMNAQEENGSWYGKWGICYIYGTWAVMTGLRSFGIPSSNP SLKRAALWLEHIQHKDGGWGESCHSSVEKRFVTLPFSTPSQTAWALDALISYYDTETPVIRKGI SYLLANPYVNEKYPTGTGLPGGFYIRYHSYAHIYPLLTLTHYIKKYRK >seq_ID 46 MLLYEKVHEEVKEKMAALQAMQQQDGTWRFCFEGSPLTDCYMIFLLTLLGQDQEIEPFVARLA ALQTNEGTWKLYEDEPDGNLSATIQAYAALLVSKMYKKEDINMKRAEVFIRKQGGITKAHFMTK FLLALHGGYEYPPLFHFPTPILFLSEDSPLSIFELSSSARIHLIPMMLCMNKRFTVSKKMLPNLDYI SGGSKEQWFREERSPLFQTLLRDVTKFLSYPLSLHYKGDKAAERFMIERIDTNGTLYSYASATF YMIYALLALGHSIQSPLISNAVLGLKTYVWNMDRWAHLQNSPSTVWDTALLSYSLQEARVPHD NEMIQKAINYLLQKQHKEKKDWSVHAPTLDAGGWGFSDVNTTIPDVDDTTAVLRALAGSRQGN PKVESAWRKGIEWVKGLQNSDGGWAAFEKGVTSKVLTHLPLDNSGDMITDPSTVDITGRVLEF FGTYAPNELQGDQKDRAIRWLIYTQEKNGSWHGKWGVCYIYGTWAALTGLRAVGVPSNHIAL QKAATWLESIQHSDGGWGESCRSSVEKKFISLPFSTPSQTAWALDALIACYDSETPTIRKGISYL LKHSTKHQEYPTGTALANGFYIRYHSYHHIFPLLTFAHYIKKYRK >seq_ID 40 MSNLLLYEKVHEEIARRTTALQTMQRRDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVKR LASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASKKYTKEDANMKRAEMFINERGGVARAHF MTKFLLAVHGEYEYPSLFHLPTPIMFLQSDSPLSIFELSSSARIHLIPMMLCLNKKFRIRKKLLPNL NHISGGGGEWFRGNRSPLFQTLVSDVKQIISYPLSLHHKGNEEVERFMKERIDENGTLYSYATA SFYMIYALLALGHSLQSTMIQKAITGITSYIWNMESGNHLQNSPSTVWDTALLSYALQEAHVPKD TNMLQHATAYLLKKQHTKKADWSVHAPALAPGGWGFSDVNTTIPDVDDTTAVLRALARSRGS EKVDYVWEKGINWVKGLQNNDGGWGAFEKGVTSNLLANLPIENASDMITDPSTPDITGRVLEL FGTYAQNELPEKQTQSAINWLMNVQEKNGSWYGKWGICYIYGTWAVMTGLRSLGIPSSNPSL KRAALWLEHIQHEDGGWGESCHSSVEKRFVTLPFSTPSQTAWALDALISYYDKETPAIRKGISY LLANRYVNEKYPTGTGLPGGFYICYHSYAHIYFPLLTLAHYIKKYRK >seq_ID 38 MSNLLLYEKAHEEIARRATALQSMQWQDGTWRFCFEGAPLTDCHMIFLLKLLGRDKEIEPFVK RLASLQTNEGTWKLYEDEVGGNLSATIQSYAALLASGKYTKEDANMKRAENFIKERGGVARAH FMTKFLLAVHGEYEYPSLFHLPTPIMFLQNDSPLSIFELSSSARIHLIPMMLCLNKRFRVGKKLLP NLNHIAGGGGEWFREERSPLFQTLVSDVKQIISYPLSLHHKGYEEVERFMKERIDENGTLYSYA TASFYMIYALLALGHSLQSSIIQNAITGITSYIWKMESGNHLQNSPSTVWDTALLSYALQEAHVPK DNKMLQNATAYLLKKQHTKKADWSVHASALTPGGWGFSDVNTTVPDVDDTTAVLRVLARSRG NEKVDHAWQKGINWVKGLQNNDGGWGAFEKGVTSNILAKLPIENASDMITDPSTPDITGRVLE FFGTYAQNELPEKQKQSAINWLMNVQEENGSWYGKWGICYIYGTWAVMTGLRSFGIPSSNPS LKRAALWLEHIQHKDGGWGESCHSSVEKRFVTLPFSTPSQTAWALDALISYYDTETPIIRKGISY LLANPYVNEKYPTGTGLPGGFYIRYHSYAHIYPLLTLAHYIKKYRK >seq_ID 55 MLLYEKVRQEVERKVTALRTMQYQDGAWRFCFEGSPLTDCHMIFLLRLLGQNGEMEPFVTRV ASLQTNEGTWKLYEDESVGNLSTTINAYVALLASGRYTKEDINMKRAEAFIRRQGGITKAHFMT KFLLALHGGYEYPSLFHFPTPMLFLPEDSPLSIFELSSSARIHLIPMMICMNKRFTVSKTILPNLDY ISGGSKKQWFREERSSLFQRLLGDVKKFLSYPLSLQHKGYKEAERFMIERIETNGTLYSYASAT FYMIYALLALGHSIQSPLISNAVLGLKSYIWNMNKGTHLQNSPSTVWDTALLSYSLQEAGVPND NQMIQKATDYLLQKQHKEKKDWSVHAPSLDAGGWGFSDVNTTIPDIDDTTAALRAIARSREGN QRIEEAWRKGIEWVKGLQNIDGGWAAFERGVTSHFLTHLPLDNAGDMTTDPSTSDITGRVLEF FGTYAPHQLKDDQKDRAIKWLMQAQEKNGSWYGKWGVCYIYGTWAALTGLRAVGVPSNHTA LQKAATWLERIQHNDGGWGESCRSSIEKHFISLPFSTPSQTAWALDALITFYDTETPVIRKGISY LLAHLNQNQDYPTGIGLPDGFYIRYHSYHHIFPILTFAHYIKKYMK >seq_ID 54 MLLYEKVRQEVERKVTALRTTQYQDGAWRFCFEGSPLTDCHMIFLLRLLGQNGEMEPFVTRV ASLQTNEGTWKLYEDESVGNLSTTINAYVALLASGRYTKEDINMKRAEAFIRRQGGITKAHFMT KFLLALHGGYEYPSLFHFPTPMLFLPEDSPLSIFELSSSARIHLIPMMICMNKRFTVSKTIFPNLDY ISGGSKKQWFREERSPLFQTLLGDVKKFLSYPLSLQHKGYKEAERFMIERIETNGTLYSYASAT FYMIYALLALGHSIQSPLISNAVLGLKSYIWNMNKGTHLQNSPSTVWDTALLSYSLQEAGVPND NQMIQKATDYLLQKQHKEKKDWSVHAPSLDAGGWGFSDVNTTIPDIDDTTAALRAIARSREGN QRIEEDWRKGIEWVKGLQNIDGGWAAFERGVTSHFLTHLPLDNAGDMTTDPSTSDITGRVLEF FGTYAPHQLKDDQKDRAIKWLMQAQEKNGSWYGKWGVCYIYGTWAVLTGLRAVGVPSNHTA LQKAATWLERIQHNDGGWGESCRSSIEKHFISLPFSTPSQTAWALDALITFYDTETPVIRKGISY LLAHLNQNQDYPTGIGLPDGFYIRYHSYHHIFPILTFAHYIKKYMK >seq_ID 189 MRSELLQLQSADGSWRLCFDSGTMPDSYFIIILRMLGYSQDEALIRQIASRILSRQLPNGTWKIY PDEEDGNLDATAEAYFALLYSGFLTKLDPRMQLAKQFILSKGGLSKIRSLLTQAIFAAAGQASWP KSMRIPLEVFFSDNGIGIDLFSLSGHARVHIVPIIMLANAQFVQHSASMPDLSDLFAGSSKRFEN DSPWIAALATLIGSLSLSELLPFESPTPQEKAVQFLFDRLEPDGTLLTYTTATMFMILVLLMLGYS SSSPLIHRMVSGIHSVICANSHVQIASSEVWDTAMLVHALRKAGVNPTSTALENAGAYLRQRQQ TQLGDWAIRNPGTPAGGWGFSNVNTLYPDVDDTTAALRAIQPYSSRTPELQADWQRGLNWVL TMRNDNGGWPAFERQGSRLPITFFNFEGAKDIAVDPSTVDLTSRTLQFLGQELGMNAGNSWIE STLRWVLSQQESNGSWYGRWGITYVHGTSAALQGLTAVGIAEDHPAVKKGVDWLLQVQNED GGWGESCISDKVRRYVPLNFSTPSQTAWALDGLTAALPKPTPALERGVDALLQSLDRHDWTY TYPTGGALPGSVYAHYASNNYIWPLLALSNIWQKYS >seq_ID 200 MALPFNQDSYKGDDEADVSKGAAKSPPSLEEAIQRSQEFLLAQQFPEGFWFGELEANVTIISHT VILYKLLGIEENFPMYKFERYLRRMQCSHGGWEIAYGIGSYLSATIEAYIALRLLNVPQSDPALQK ALRVILDSGGVTKARIFTKICLALLGSFDWRGIPSLPPWLILCPTWFPLSIYEVSSWARGCIVPLL VILDKKPVFKVSPEVSFDELYAEGREHACKIIPISGDWTSKFFITVDRVFKMMERLRVVPFRQW GIREAEKWILERQEESGDYVNIFPAMFYSVMCMKVLGYETTDPVVQRALLGFKGFTIETADECK VQSTVSPIWDTAFIVRALVDSGIPPDHPALQKAGQWLLQKQILKHGDWAFKDRQNPVNQRGFA CLQRDSQIETADECRVQSTLSPVWDTAFVVKALVDSGIPPNHPALQKAGQWLLQNQTLTHGD WAFKTQSGHLAAGGWAFQSHNRWYPDADDSAAVMMALDCIELPDEDVKNGAIARGLKWISAL QSRNGGWAGYDKNCDQQWINKVPFNDLNGILDVPTADVTARVLEMVGRLSRLGAVGTPYSPR HCTLVESIPHLLLPETIARGLAYLRREQEGEGCWWGKWGVNYIYGTCGALLALSQVAPTTHQE EIARGAKWLAQVQNRCDKQKAAQGPRDGGWGESCFSYDDPALKGQNDASTASQTAWAVQG LLAAGDALGKYEVEAIEQGVQYLLATQRKDGTWHEAHFTGSCFAQHFYVRYHYYAQHFPLSAL GLYRTRILQHQ >seq_ID 139 MVADERSALIDALKRSQSVDGSWRFPFETGISTDAYMIILLRTLGIHDEPLIQALVERIESRQDAN GAWKLFADEGDGNVTATVEAYYALLYSGYRKKTDSHMQKAKARILEVGGLERVHLFTKVMLAL TGQHSWPRRFPLPLVFFLLPPSFPLNMYDLSVYGRANMVPLLVVAERRYSRKTDNSPDLSDLA ASRNDWRLPDTEALWSYVKRSLTGLPAWLHRAAEQRAVRYMLEHIEPDGTLYSYFSSTFLLIFA LLALGYPKDDPHIARAVRGLRSLRTEIDGHTHMQYTTASVWNTALASYALQEAGVPPTDRTIEK ANRYLLSRQHIRYGDWAVHNPYGVPGGWGFSDVNTMNPDVDDTTAALRAIRRAAAKETAFRH AWDRANRWLFSMQNDDGGFAAFEKNVGKRFWRYLPIEGAEFLLMDPSTADLTGRTLEYFGTF AGLTKDHSAIARAIDWLLDHQEADGSWYGRWGICYVYGTWAAVTGLSAVGVPIDHPAMQKAV RWLLSIQNDDGGWGESCKSDGAKTYVPLGASTPVHTAWALDALIAAAERPTPEMKAGVRALV RMLHHPDWTASYPVGQGMAGAFYIHYHGYRYIFPLLALAHYEQKFGPFVD >seq_ID 13 MAQMASSLGSPRLLLRMGREAAQQQHLASGTEVQKALRLAVGHSLDLQRTDGAWCGEVHSN ATFTAQYVFLQQQIGLPLDPTEIEGLSRWLFSQQNEDGSWGLGPGLGGDVSTTTETYLALKILG VSPEDPRMAAARTSIIKAGSLPATRMFTRVFLASFGLIPWSAVPPLPAELILLPTLFPVNIYNLSS WARATCVPLLLIRHHEPLHSLPNGRHAENDFLDELWTKDIPRDFCYTTPLSRMWRLGDYAGIFF TSADHGFRFLGQYFNSPLRNLSRRKIINWILDHQEQSGEWAGYWPPQHNNIWALSLEGYSLDH PVLRRGIAAVKSFVLHDATGMRAQVTVSQVWDTALMSIALSDSAPSTGIISPTQAIDWLMHHEV ASHRGDWRVLRPKLATGGFCFEEFNTLYPDVDDTAAVIMALIKSNPAHLISGCVRQCFGMMMA GRHGYSLDCQLETRLRASSQLAIAYLLGCQENNGSWWGRWGVNYLYGTSNVLCGLAYYYDR SSLSKGDGKSNSNIVSAVDRASEWLKARQHSNGGWGEGLESYDNAQLAGCGQPTASQSAW VTMALLNYLSPTDEVIQRGVSYLVRNQVKYGDESRATWPLERYTATGFPGHLYMEYDYYRHYF PIMALGRYVNKLSGSHKLL >seq_ID 198 MEDLTQKLQQALQLASRALLNERVRPGLAHWEGELSTSALSTATAVMALFQYAKCQQASGRL QKVFDGKSEGDWRLIEQGLAWLLQHQLADGGWGDTDKSISNISTTMLAHATLVACREAVRQK SLVLNASDIDAAIERSGRLIEELGGIQAIRDRYGKDHTFSVPILTHAALAGLVSWNEIPALPYELAL LPHRFFEVIQLPVVSYALPALIAIGQTLHLRQRTWNPWWWVRRAAIPGTLQKLQSIQPESGGFL EATPLTSFVTMCLASVGRVDHPVTQAGLKFIRDSVRPDGSWPIDTNLATWVTTLSINHLGAEAF SSDEREALMRWLLQQQYRTMHPYTNAAPGGWAWTNLSGGVPDADDTPGAMLALMELDRVS VSSQESLSIEQALYQAALWLIKLQNRDGGWPTFCRGWGALPFDRSSNDITAHCLRALIQYERRL NDVTVDATGDTTSRPLAVEVPSPKLREQMQRSIQQGFEYLEKTQREDGSWLPLWFGNQHSPD DENPLYGTARVLLAYADAGLEGSSAALRGCDWLVRHQHADGAWGPGTSIETADTSDAESDVE GEPASIEETALALMALCRFDATHNVLHRGASWLITKVENETWREPTPIGFYFAKLWYYEKLYPQ VFTVGALKALALRLGSALTTVSENEPAPSSAEPPIPPIATDRVADSMHLQRTSPSINLANGGITLA >seq_ID 252 SPVWDTVLTLLALDDCGYNDCYSEEVDKAVQWVLDQQVLSKGDWSVKLPNVEPGGWAFEYA NTRYPDTDDTAVALIVLSQFKDDPKWKERGINQAIERGVNWLFEMQCKNGGWGAFDKDNDKT LLTKIPFCDFGEALDPPSVDVTAHIVEAFGKLGYSKDHPKIAHAIEYLKEEQEADGAWFGRWGV NYVYGTGAVLPALEAIGEDMSQPYIRKAANWLVLHQNEDGGWGE >seq_ID 253 SPVWDTVLTLLAFDDCDKNEAYQASVEKAVQWTLDNQVLRKGDWSVKLPDVEPGGWAFEYA NTFYPDTDDTAVALIVLSQFRDVEKWQEAGIEKAIERGVNWLFAMQSKNGGWGAFDKDNDNN FITKIPFCDFGEALDPPSVDVTAHCIEAFGKLGLSRARPEIARGLDYLKSEQEADGAWFGRWGV NYVYGTGAVLPALEAIGEDMSQPYIRKAANWLILRQNEDGGWGE >seq_ID 257 SPVWDTXLTLLALDDCDLNERQSKEVEKAVQWVLNQQVLRPGDWCVKVPKVQPGGWAFEYK NYFYPDTDDTAVALIVLSQFRDDPKWQEKNIEQAIDRGLNWLIGMQCKGGGWGAFDKDNDKT YLTKIPFCDFGEALDSPSVDVTAHIVEAFGKLGLGKSHPAMIRAIDYLKAEQEQDGAWFGRWGV NYIYGTGAVLPALEAIGEDMRAPYIAKACDWLIAVQQEDGGWGE >seq_ID 254 SPVWDTLLTLLAYDDSGQNERKADEVEKAVDWVLAXQVLRPGDWKVKAPNLEPGGWAFEYA NYFYPDTDDTAVALIVLSQFRNDAAWKEKGIEQAIEKGVNWLFGMQCKGGGWGAFDKDNDKQ FLTKIPFCDFGEALDPPSVDVTAHIVEAFGKLKFSKDHPNIRRAIDYMKDEQEADGAWFGRWGV NYIYGTGAVLPALEAIGEDMFAPCIGRACDWLVSRQNDDGGWGE >seq_ID 255 SPVWDTLLTLLAYDNSGHNARKASEVEKAVDWVLAQQVLRPGDWNVKAPNLEPGGWAFEYA NYFYPDTDDTAVALIVLSQFRNDAAWKDKGIEQAIEKGVNWLFGMQCKGGGWGAFDKDNDR QFLTKIPFCDFGEALDPPSVDVTAHIVEAFGKLKFSKDHPNIRRAIDYTKDEQEDDGAWFGRWG VNYIYGTGAVLLALEAIGEDMSAPYIGRACDWLVSRQNDDGGWGE >seq_ID 256 SPVWDTLLTLLAIEDSGQSVKRAQEVEKAVDWVLSQQVLRPGDWKVRAPHLEPGGWAFEYAN YFFPDTDDTAVALIVLSQFRNDAAWKAKGIETAIEKGVNWLLGMQCKGGGWGAFDKDNDKTYL TKIPFCDFGEALDPPSVDVTAHIVEAFGKLGFSKDHPNIARAIEYLKSEQESDGXWFGRWGVNY VYGVGAVLPALEAIGEDMSAPYIGRACDWLVSKQNSDGGWGE >seq_ID 258 SPVWDTVLTMLAIHDCGADKQYAPQMDKAIDWLLANEVRHKGDWAVKLPDVEPGGWAFEYS NACYPDLDDTAVALIVLAPYRNDPKWQARDIEGAVERAVDWTLAMQCKNGGWGAFGKDNDK AILTKIPFCDFGEALDPPSVDVTAHVLEALAALGYDNSHPAVARAIRYLRDEQEPDGSWWGRW GVNYIYGTAAVLPALKAMGVDMNEPFVHKAADWIGSVQNEDGGWGE >seq_ID 302 SPVWDTSLVLVAMQEAGVPVDHPALVKAAQWLLDREVRLKGDWRVKSPDLEPGGWAFEFLN DWYPDVDDSGFVMLALKDIKVRDKKQKSQAIKRGIAWCLGMQSANGGWGAFDKDNTKYLLNK IPFADLEALIDPPTADLTGRMLELMGTFNYPKSHVAVVRALGFLKSVQEPEGPWWGRWGVNYI YGTWSVLGGLDAIGEDMSQPYIRKAVNWLKSKQNLDGGWGEVCETYEDRSLMGCGPSTPSQ TSWALLSLFSAGEINAKAVLRGIKYLVETQNQDGSWDEDAYTGTGFP >seq_ID 271 SPVWDTAISVISLAXSGMERGHPALVRAAXWLMSKEIKTAGDWKVTNPAGPVGGWAFEFNNA FYPDIDDSAMVMMALRHVHLDEHTAHRREKACLRGLNWLLSMQSRTGGWAAFDKDNTKVIMT KIPFADHNAMIDPPWADITGRVLEFLGYIGYDQSYPAVARAARFLREEQEEDGSWFGRWGVNY IYGTWQVLRGLAAIDEDMSQPYIRRAAEWLRSVQPPDGGWGETCATYHDPSLKGKGPATPAQ TAWAVMGLMAAGIYDESVSRGIDYLVRTQRPDGTWDETEYGTGFP >seq_ID 299 SPVWDTALVLVAMQEAGVPVDHPALIKSAQWLLDLEVRRKGDWHVKSPDLEPGGWAFESLND WYPDVDDSGFVMLFIKDIKVRDKKLKDQAIKCGIAWCLGMQSENGGWGAFDKDNTKHLLNKIP FADLEALIDPPTADLTGRMLELMGNFNYPKSHQAAVKALDFLKVEQEPEGPWWGRWGVNYIY GTWSVLCGLEAIGEDMSQPYIKKAVNWLKSKQNLDGGWGEVCDSYADRSLMGCGPSTASQT SWALLSLFAAGEVSSKAALRGVEYLLSTQKLDGTWDEDAFTGTGFP >seq_ID 314 SPVWDTALAVRALAAAGVPPEHPAMVKASEWLLTQQIFKPGDWSIKCPDLPPGGWAFEFVNN WYPDVDDSSMVLVALKDGLADAAKHQAALQRGINWCLGMQSKNGGFASFDKDNTKEWLNSL PFGDLKALVDPPTEDITARILEMMGAFGHGLDHPVAARALAYLHQTQRPEGPWWGRWGVNYI YGTWSVLVALKRIGEDMSRPYVRRAVDWVKAHQNPDGGWGEFCESYRNPELMGKGPSTAS QTAWALLGLFAAGEVHAPEVTAGVDYLVKTQDSLGRWDEEQFTGTGFP >seq_ID 251 SPVWDTVLTMLSVQDCDADENSENAPAIEKAIEWLLANEVRTGGDWQEKVKGVEPGGWAFEY KNASYPDTDDTAVAMMALAPYRTEEKWKKKGLPEALKRAAEWNIAMQCSNGGWGAFDKDND KTILCKIPFCDFGEALDPPSVDVTAHVLEGLAALDYPPEHPAIQRAVQFIKDEQEPDGSWWGR WGVNFIYGTAAALPALKAVGEDMRAPYIDRAAKWIVDHQNEDGGWGE >seq_ID 312 SPVWDTALAVRALAAAGVPPEHPAMVQASEWLLTQQIFKPGDWSVKCPDLPPGGWAFEFVN NWYPDVDDSSMVLVALKDGLADAAKHQAALQRGINWCLGMQSKNGGFASFDKDNTKEWLNA IPFGDLKALVDPPTEDITARILEMMGAFGHGLDHPVAVRAMAYLHETQRPEGPWWGRWGVNYI YGTWSVLVALKRIGEDMSRPYVRRAVDWVKAHQNLDGGWGECCESYRNPELMGRGPSTAS QTAWALLGLFASGEVHTPEVKAGVDYLVKTQNSLGRWDEEQFTGTGFP >seq_ID 250 SPMWDTVLTTLAVQDAGVDQEPEFKPAMERTLEWLLKNEVRTGGDWQQKTRGVEPGGWAF EYANASYPDNDDTAVALIVLAPFRHDPKWQARGIQHVIDRAVNWMFAMQCDNGGWAAFDLDN DKAILTRIPFCDFGEALDPPSVDVTAHVLEALAALGYSREHPAVRRAIAFLKEDQEPDGSWFGR WGVNFIYGTAAALPALKAMDEDMTQDWITRAADWMRSRQNDDGGWGE >seq_ID 260 SPVWDTVLTLLAIQDADKQDDMAAEVDRAIGWLLSKEVRTNGDWSVKLPDVEPGGWAFEHEN ARYPDTDDTAVAVMVLAPYRHHPKWRKRGLPEALDRAISWMRAMQCRNGGWGAFDKDNDN AFLCVIPFCDXGEALDPPSIDVTAHALEAFAAMGFGPEDTTVARALDYMSKEQEADGSWWGR WGVNYIYGTAAALPAYKAFGQDMRDFKLMKAADYLRAKQNADGGWGE >seq_ID 259 SPVWDTVLTLLAMEDCEATEEHAAAIEQAIEWLLENEVRTPGDWQMKVPDADPGGWAFEYAN AAYPDVDDTAVAILVLARYRDDPKWQAKGLPQAIDRAVAWVLAMQCSNGGWAAFDKDNDKSI LCKIPFCDFGEALDPATVDVTAHVLEALAAVGYGPDHPAVRRGLDFLYAEQEADGSWWGRWG VNYVYGTGAALPAFKAIGADMRDPRMLKAADWILRCQNKDGGWGE >seq_ID 261 SPVWDTVLTLLAIQDADKQEEMAGEIDKAIGWLLSKEVRTKGDWSVKLPRVEPGGWAFEHENA RYPDIDDTAVAIMVLAPYRDHPKWKKRGLPEALDRAIAWMRAMQCRGGGWGAFDKDNDKQIL CTIPFCDFGEALDPPSIDVTAYALEAFAAMGYGPDDKTVARALKYMSKEQEADGSWWGRWGV NYIYGTAAALPAYKALGQDMRDPGLMKAADYLRDKQNADGGWGE >seq_ID 262 SPVWDTVLTLLAMQDADRTDKHKAAVDKAIQWVLDQEVRTPGDWCVQTPDVEPGGWAFEYE NARYPDVDDTAVAIMVLAPYQDDPKWRKRGLPDALARAIAWIRAMQCKNGGWGAFDRDNDN SMLTVIPFCDFGEALDPPSVDVTAHALEAFHMMGYGPEDPTVARALAYLDAEQEQDGSWWGR WGVNFIYGTSAALPALKAMGRDMRDPRYTKAADYLRAVQNDDGGWGE >seq_ID 275 SPVWDTLLALLALQDCDRELTAEMSRALDWVLANEVRYHGDWTKKVKGVEPSGWAFERANL NYPDIDDTAVALIVLARLPRAWLDEPRIRATIDRVLGWTLAMQSSNGGWAAFDKDNDRPIITKIP FCDFGEALDPPSADVTAHVLEALGLLGFDRRHPAVERGLRFLRSEQEADGSWFGRWGVNYVY GTAAVLPGLAAIGEDMTQDYIRRANDWLIAHQNPDGGWGE >seq_ID 280 SPVWDTLLSLVALQDCGKELTPARERALEWILGREIRTRGDWAKKVKNVEASGWAFERANLHY PDIDDTAVALIMLARLPRAWLDQPRIRAVIDRALGWTLAMQSSSGGWAAFDKDNDRLIITKIPFC DFGEALDPPSADVTAHVLEALGILGFDRQHAAVRHGLKFLRSEQEADGSWFGRWGVNHVYGT GAVLPALAAIGEDMAQDYVRRAADWLVAHQNADGGWGE >seq_ID 277 SPVWDTLLALLAMQDCERELTPQMERALDWVLANEVRYYGDWSKKVRGVEPSGWAFERANL NYPDIDDTVVALIVLARLPRALLDQPRIRAVIDRALGWTLAMQSSNGGWAAFDKDNDHLIITKIPF CGFGEALDPPSADVTAHVLEALGLLGFDRHHPAVARGYQFLRKEQEADGSWFGRWGVNHIY GTAAVLPALAAIGEDMSQPYIRAAAEWIIAHQNADGGWGE >seq_ID 300 SPVWDTALVLVAMQXAGVPVXHPALVKSAQWLLDLEVXXKGDWQVKSPELEPGGWAFXFLN DWYPDVDDSGFVMLSIKXIKVRDKKHKEQAIKRGISWCLGMQSDNGGWAAFDKNNTKYLLNKI PFAXLEALIDPPTAXLTGRMLELMGNFNYPKTHKAAVQALEFLXMEXEPXGPWWGRWGVNYIY GTWSVLCGLEAIGEDMAQPYIKKSINWLKSKQNMDGGWGEVCESYGDRSLMGCGPSTASQT SWALLSLFAAGEVHSKAATRGIEYLLATQKLDGTWDEDAYTGTGFP >seq_ID 279 SPVWDTLLXLLAMQDCERESTPSMERALDWXXANEVRYYGDWSKKVRGVEPSGWAFXRANL NYPDIDDTDVALIVLARLPRALLDQSRVHAVIDRALGWTLXMQSSNGGWAAFDKDNNHLIITKIP FCDFXEALDPPSADVTAHVLEALGLLGFNRNHPAVERGYRFLRSEQETDGSWFGRWGVNHVY GTXAVLPALAAIGEDMTQPYIRSAAEWIIAHQNADGGWGE >seq_ID 264 SPVWDTLLTLEALLDCNLSPKTFTGMQAAVDWILSKQIVTPGDWQIKVPGVSCGGWAFERANT FYPDMDDTAVAMIVLARIRRYYNDSSRIDRALACATDWILSMQCSNGGWAAFDLDNTNDLVTRI PFSDFGEMLDPPSVDVTAHVVEALGCLGRTRNDPAVARAVAYILDEQEPEGSWFGRWGVNHI YGTGAVLPALAAVGTDMSAGYITRAADWVATHQNADGGWGE >seq_ID 19 GGWMFQASISPIWDTGLTVLALRSAGLPPDHPALIKAGEWLVSKQILKDGDWKVRRRKAKPGG WAFEFHCENYPDVDDTAMVVLALNGIQLPDEGKRRDALTRGFRWLREMQSSNGGWGAYDVD NTRQLTNRIPFCNFGEVIDPPSEDVTAHVLECFGSFGYDEAWKVIRKAVEYLKAQQRPDGSWF GRWGVNYVYGIGAVVPGLKAVGVDMREPWVQKSLDWLVEHQNEDGGWGE >seq_ID 278 SPVWDTLLSLLAMQDCERGFTPSMERALDWVLANEVRYYGDWSKKVRGVEPSGWAFERANL NYPDIDDTAVALIVLARLPRAQLDQPRIREVIDRALGWTLAMQSSNGGWAAFDKDNDHLIITKIP FCDFGEALDPPSADVAAHVLEALGLLGFERKHPAVERGLKFIRSEQEADGSWFGRWGVNHIY GTAAVLPALXAIGEDM >seq_ID 315 SPVWDTALAVRALAAAGLPPDHPFMTQATSWLLTQQIFKPGDWCIKCPDLPPGGWAFXFHNN WYPDVDDSSMVLVALKDGLPDTARHQAALQRGINWCLGMQSKNGGFASFDKDNTKEWLNAL PFGDLKALVDPPTEDITARILEMMGAFGHGLDHPTADRALAFLRRTQHPEGPWWGRWGVNYL YGTWSVLVALKRIGXDMSRPYVQRAVNWIKSHQNPDGGWGEVCESYRHPELMGQGPSTASQ TAWALLGLLAAGEIQAAEVKAGVDYLVKTQNAQGRWDEKYFTGNWLP >seq_ID 297 SPVWDTALVLQAMQEASIPLDHPALVKAAQWLLDREVRIKGDWKIKSPGLEPGGWAFEFQND WYPDVDDSAAVLIAIKDIQVKNNKAKQGAVRRGIDWCLGMQSKNGGWGAFDKDNTKHLLNKIP FADLEALIDPPTADLTGRMLELMGNFGYDKHHPQAVHALEFLKKEQEPEGPWFGRWGVNYIY GTWYVLIGLEAIGEDMNQPYIKKAANWIKSRQNIDGGWGE >seq_ID 17 QASISPVWDTGLAVLALRAAGLPADHDRLVKAGEWLLDRQITVPGDWVVKRPNLNPGGFALQF DNVYYPDVDDTAVVIWALNTLRLPDERRRRDAMTKGFRWIVGMQSSNGGWGAYDVDNTSDL PNHIPFCDFGEVTDPPSEDVTAHVLECFGSFGYDDAWKVIQRAVAYLKREQKPDGSWFGRWG VNYIYGTGAVVSALKAVGIDMREPYIQKALDWVEQHQNPDG >seq_ID 303 SPVWDTALVLVAMQEAGVPLDHPALVKAAQWLLDREVRIKGDWRIKSPDIEPGGWAFEFLND WYPDVDDSGFVMLAIKDVKVRDKKKKEQAIKRGINWCLGMQSANGGWGAFDKDNTKYLLNKI PFADLEALIDPPTADLTGRMLELLGTFNFPKDHHAIERALEFIQLEQEPEGPWWGRWGVNYIYG TWSVISGLEAIGEDMSQPYIRKTVNWLKSKQNMDGGWGE >seq_ID 298 SPVWDTTLVLVAMQEAGVPVDHPALVKSAQWLLDLEVRRKGDWQVKSPDVEPGGWAFEFMN DWYPDVDDSGFVMLAIXNIRVRDKKHQEQAIKRGIAWCLEMQSENGGWGAFDKDNTKYLLNKI PFADLEALIDPPTADLTGRMLELMGNFDYSASYPAAVRALEFLKKEQEPEGPWWGRWGVNYIY GTWSVLCGLEAIGEDMSQPYIRKAVNWLKSKQNLDGGWGE >seq_ID 301 SPVWDTALALVAMQEAGVPKDHPALVKAAQWLLDLEVRRKGDWQIKSPELEPGGWAFEFLND WYPDVDDSGFVIMAIRDIKAPDKKHKEQAIKRGIAWCLGMQSKNGGWGAFDKDNTKHLLNKIP FADLEALIDPPTADLTGRMLELMGSFDYPMDHPAAARALEFLKKEQEPEGPWWGRWGVNYIY GTWSVLCGLESIGEDMSQPYIKKAVNWLKSKQNMDGGWGE >seq_ID 276 SPVWDTLLTLLAMEDCDRGLTPSMQRALEWVLAQEVRYAGDWSKKVKGVEPSGWAFERANL NYPDIDDTAVALIVLARLPRAWLDEPRIRATIDRVLGWTLAMQSSNGGWAAFDKDNDRPIITKIP FCDFGEALDPPSADVTAHVLEALGLPGFDRRHPAVERGYKFLRSEQEADGSWFGRWGVNHIY GTAAVLPALASIXEDM >seq_ID 283 SPVWDTCLTSNALVESGGDTSAPHVHRSVQWLLNQEIRNHGDWSVKAPKVGPSGWAFEFAN KVYPDVDDAAEVIIALANYSNDSGTAPPDAIARGVRWISGMQSSNGGWGSFDKNNTSFFVTRL PFFDFGEVIDPPSVDVTAHVIEALAVAGWQEKASKQIQKALDYIWSEQEADGPWFGRWGINYIY GTCAVLSALEAIGYDMADARVVKALKWIEECQNADGGWGE >seq_ID 307 SPVWDTPWMIEALLETGVPPGDPALLRAGRWLMSKQITGVRGDWAMKSPKGKPGGWAFEFE NDYYPDVDDTIQVLTALCKLSIPWREKEKAVMQGIDWLISMQNDDGGWGAFDRNQTRWIVNRI PFSDHKACLDPSSPDITGRMVEFLMRRNYSTSHPSVKKALKYIRETQEDFGAWFARWGINYIY GTWCVLTALAAMGIGHTDSRVAKAVAWLSSVQRPDGGFSEAADTYHPHKPFESYSESVPSQS AWALMGLVAGGAVHSPAAARAACYLINNRNLNNGWDERHYTGTGFP >seq_ID 267 SPVWDTAISVIALAESGLHRGHPSLVQATEWLVANEIRRGGDWQVKNPTAPISGWAFEFKNDF YPDVDDTAMVLLALRHVHLYNDDVSQDREKSYLRGLNWMLSMQCKNGGWAAFDRDNVKTIF EKIPFADHNAMIDPPSVDITGRVLELLGYVGYDKSYPCVTKALEYIKKDQEADGSWYGRWGVN YIYGTWQVLRGLAAIGEDMQSEYVQKAVRWMKSVQNPDGGWGE >seq_ID 309 SPVWDTVLSITALADADLPRTHPAMRRAVAWVLGKQVLCEGDWRVKNRRGEPGGWSFEFNN NFYQDNDDTAAVLIALHKARLPDEAKGEAMQRGLRWLLSMQCDDGGWSAFDVNNNKRLLNKI PFADLESMLDPSTCDLTGRTLEALGSIGFPFTHRIVQHAVRFIRQHQEADGAWYGRWGVNYIY GTCHVLCGLLSVGEDMHQPYVQRAVQWLIEHQNADGGWGE >seq_ID 202 MVYSYEMMVLLDYPEDHPLRVECKAALKKLVVHRDDGSSYCQPCLSPVWDTAWSVMALEQA PSDARTETAIARAYDWLTDRQVLDLRGDWENNAAPSTPPGGWAFQYENPYYPDIDDSAVVLA MLHARGKRTGQPGRYEMPVARCLDWIIGLQSRNGGFGAFDANCDRDFLNAIPFADHGALLDP PTEDVSGRVLLALGITERPQDATARERCIQYLRDTQQPDGSWWGRWGTNYIYGTWSVLAGLG LAGVDRKLPMVRNGLQWLRGKQNADGGWGETNDSYARPELAGKHEDGSMAEQTAWAMLG QMAVGEGDADSVHRGAAYLLDAQNEDGFWMHPYHNAPGFPRIFHLKYHG >seq_ID 306 SPVWDTPWTVMALLEAGVPSNDPALLRSGRWLLAKQITDTKGDWAIKNKNTAPGGWSFEFEN KYFPDVDDTIEVLHCLHKLAIPWREKEKPCRLGIDWLLSMQNDDGGWGAFDKNQKRQVVNRIP FSDHGACLDPSSPDITGRMIEFLATQKFNSEYESVKRALKYIWKTQEDFGGWHARWGINYIYGT WCVLTGLRAIGFNMTDRRVQKALNWLESIQNKDGGFGESPASYEECRYIPWKESVPSQTAWA LMALVAGGGAGSAPAENAATFLINYRNSNGVWDEECYTGTGFP >seq_ID 281 SPVWDTLLTLLAYQDCELEMNDSAGRALDWILSQENSYRGDWAHRNKKLEPSGWAFERANLH YPDIDDTSVALIVLARLPQAVRSRPDIKSAIDRALAWTLGMQCRNGGWAAFDRDNDKLIITMIPF CDFSEALDPPSADVTAHVVEAMAHLGFDRSHKAVEKAYQYLLAEQEDDGSWFGRWGVNHIY GTAAVLPALAALGEDATVPHVKRAADWISAHQNTDGGWGE >seq_ID 310 SPVWDTALAVRALAAAGLPPEHPAMVKASEWLLTQQIFKPGDWSVKCPDLPPGGWAFEFVNN WYPDVDDSSMVLVALKEGLADAAKHQAALQRGINWCLGMQSKNGGFASFDKDNTKEWLNAIP FGDLKALVDPPTEDITARILEMMGAFGHGLDHPVAVRGLAYLHQTQRPEGPWWGRWGVNYIY GTWSVLVALKRIGEDMSRPYVRRAVDWVKAHQNPDGGWGE >seq_ID 311 SPVWDTALAVRALAAAGLPPEHPAMVKASEWLLTQQIFKPGDWSVKCPDLPPGGWAFEFVNN WYPDVDDSSMVLVALKDGLVDAAKHQAALQRGINWCLGMQSKNGGFASFDKDNTKEWLNAI PFGDLKALVDPPTEDITARILEMMGAFGHGLDHPVAVRALAYLHQTQRPEGPWWGRWGVNYI YGTWSVLVALKRIGEDMNRPYVRRAVDWVKAHQNLDGGWGE >seq_ID 290 SPIWDTAKAVNALHESGLPSDHPQLKAAARWLVEKEVRKPGDWKMRVPHVDVGGWPFQFRN EFYPDVDDTAAVVMALGRVDERDVPGIKDSITRGINWVTQMQCSCGGWAAFDVDVKREFLTK VPYADHNAMLDPPCPDITGRCLEMYGRFPGVRKDADVQRVIEKGIEYLKKTQEPDGSWYGRW GVNYIYGTWQSLKGLAAVGEDPSQPYIQKAAHFLKTHQNSDGGWGE >seq_ID 292 SPVWDTAKAVNALHESGLPSDHPQLKAAARWLVEKEVRKPGDWKMRVPHVDVGGWPFQFR NEFYPDVDDTAAVVMALGRVDERDVPGIKDSITRGINWVTQMQCSCGGWAAFDVDVKREFLT KVPYADHNAMLDPPCPDITGRCLEMYGRFPEVRKDANVQNVIAKGIEYLKKTQEPDGSWYGR WGVNYIYGTWQSLKGLAAVGEDPSQPYIQKAAHFLKTHQNSDGGWGE >seq_ID 293 SPVWDTCLSLAALTEAGAQNDHPAVKQAVEWLLDHQIFVEGDWCAQASGLEPGGWAFQYEN DKYPDVDDTGMVLMSLLRAGVHDKEHKRKRVNQALNWVLGMQNPDGSWGAFDIENNYEYLN KIPFADHGALVDPGTADLTARCVELLAMLGYDATFPPVKRALEFLEHDQEEDGSWYGRWGVN YIYGTWSVLCALGAIGEDVAKPYVRKSVQWLQDTQNEDGGWGE >seq_ID 313 SPIWDTALAVRALTAAGMPPEHPAMVKASEWLLTQQIFKPGDWSVKCPDLPPGGWAFEFVNN WYPDVDDSSMVLVALKEGLADTAKHQAALQRGINWCLGMQSKNGGFASFDKDNTKEWLNAIP FGDLKALVDPPTEDITARILEMMGAFGHGLDHPVAVRALAYLHETQRPGGPWWGRWGVNYLY GTWSVLVALKRIGEDMSRPYVRRAVDWVKDHQNLDGGWGE >seq_ID 304 SPVWDTPWMVMALLEAGVPTDXPGLLRAGRWLISKQITGVHGDWAVKNRHALPGGWSFEFE NDYFPDVDDTIEVLHVIHRLAIPWEEKSECCRLGLDWLLSMQNDDGGWGAFDRNQTLVMVNRI PFSDHAACLDPSSPDIVGRVLEFLASRSFSREHPAVKRALDYIWREQSPFGGWWARWGIDYLY GTWCVLTGLRAIGWDMEDPRVRKAVAWLESVARPDGGYGESPESYRDHSYVEWKRSVPSQT AWALMGLVAGGVGHGKAARGAADYLLTSRNAQGGWDEMDYTGTGFP >seq_ID 291 SPMWDTAKAVNALHESGLPSDHPQLKAAARWLVEKEVQKPGDWKMRVPYVDVGGWPFQFR NEFYPDVDDTAAVVMALGRVDERDVPGIKDSITRGINWVTQMQCSCGGWAAFDVDVKREFLT KVPYADHNAMLDPPCPDITGRCLEMYGRFPEVRKDVDVQRVIEKGIEYLKKTQEPDGSWYGR WGVNYIYGTWQSLKGLAAVGEDPSQPYIQKAAHFLKTHQNSDGGWGE >seq_ID 318 SPVWDTGLALHALLESGMDPDDPAIAKAMHWLDEREITDVAGDWAEQRPGLAPGGWAFQYR NDHYPDVDDTAVVGMAMHRANPQARPETLERTRAWIEGMQSQNGGWGAFDADNTHYHLNHI PFADHGAMLDPPTADVSARCLGMLSQMGYDRDHPSIQRAIAYLKNDQEEDGSWFGRWGTNYI YGTWSVLSALNAAGEDMSQPYIRKAVDYLTNFQREDGGWGE >seq_ID 294 SPVWDTCLSLAALTEAGAQNDHPAVKQAVEWLLDHQIFVEGDWCDQAPGLEPGGWAFQYEN NKYPDVDDTGMVLMSLLRAGVHDKEHKRKRVNQALNWVLGMQNPDGSWGAFDIENNYEYLN RIPFADHGALVDPGTADLTARCVELLAMLGYDATFPPVKRALEFLEQDQEEDGSWYGRWGVN YIYGTWSVLCALGATGEDVAKPYVRKSVQWLQDTQNEDGGWGE >seq_ID 320 SPVWDTCLGLHALLEAGEPREAPSVKKAVDWLLEREITETYGDWVWRRPHLKPSGWAFQYW NNYYPDVDDTAVVVMALDRVGDPRCRPAIERACEWIIGMQSTSGGWGSFDPENEFTYLNHIPF ADHGALLDPPTVDVTARCISMLAQVGYRHDHPAIRKSVXFILREQEKDGSWYGRWGTNYVYG TWSALSALNAVGEDMSSPVVRKGVAWLEAFQQPDGGWGE >seq_ID 295 SPVWDTCLSLTAMTESGAHPEHPAVKQAVEWLLDQQIFVKGDWADQAKNLEPGGWAFQFEN DRCPDVDDTGMVLMALLRAGVQDKEHKIKRINQAVNWVLGMQNPDGSWGAFDIGNDHEYLN NIPFADHGALVDPGTADLTARCVELLAMLGYGPDFPPIQRAVAFLERDQEEFGAWYGRWGVN YIYGTWSVLSAIGILGEDYAKPYVRKAVEWLKEIQNDDGGWGE >seq_ID 324 SPVWDTSLAAHALLEAGEPNDPEVIGLLDWLKDKQILTTVGDWSARRPNLRPGGWAFQYENP HYPDVDDTAVVAMAMHRQGDPKYAEAIARACEWLAGMQSSSGGWGAFDPENEHFYLNSIPF ADHGALLDPPTVDVTARCVGCLAQVDAERFASEIQAGIDYIKREQEEDGSWFGRWGANYVYG TWSALVALNKAGEDMNTPYIRRAVDWLKARQRPDGGWGE >seq_ID 296 SPVWDTCLSLNALTEADMPANDPRVRAAVQWLFDRQIFVRGDWSENAPELEPGGWAFQYEN DKYPDVDDTGMVLMSLLRANAHEHDAQRKRMNQALNWVLGMQNSDGSWGAFDIDNHYTYL NNIPFADHGALVDPGTADLTGRCIELFGMLGYDKNFTPARRGIEFLKRDQHPCGGWYGRWGV NYLYGTWSVLTALGAIGEARDAPYLRRAVEWLYSVQNDDGGWGE >seq_ID 305 SPVWDTPWMVMALLEAGCPANDPXLIRAGRWLKAKXITEVRGDWAVKNRKALPGGWSFEFE NDYFPDVDDTIEVLSVIHRLSIPWNEKAKSCRLGLEWXLSMXNRDGGWGAFDREQXFKVVNRI PFSDHAACLDPSSPDITGRMVEFLASXNFSKGHVAVRRALDYIWKQQAXFGGWWARWGIDYL YGTWCVLTGLASLGFXMDDPRARKAADWLESIQHADGGFGESPESYREDSFVDWKRSVPSQ TAWALMGLVAAGRASGAAAQRAAAWLLDNRNTNGSWDEQDYTGTGFP >seq_ID 282 SPMWDTSLAAHALMEADGRGDPKDNPRLISAMDWLADKQILDHVGDWAVRRPDVRPGGWAF QYENPDYPDVDDTAVVVMAMHRADPERYEMSIDRACEWLVGMQSKNGGWGAFEPENEHYY LNSIPFADHGALLDPPTVDVTARCVGALAQVDRDRYAAEIANGIRSIRREQEDDGSWFGRWGA NYVYGTWSALVALKGAGEDMQQPYIRRAVDWLKARQRSDGGWGE >seq_ID 316 SPVWDTAWAVIGLCESGMERTHPAVRSAIRWLYSMQILRPGDWAVKNPLTEPGGWAFEFHND FYPDNDDTAAVLMGLLFSDLNDEENHRAFERGVRWLLSMQNNDSGWGAFERNVDNKIFDQIP FNDQKNMLDPSTADVTGRVVELLGRIGRRLGGSFSDEPYVRQAIEFLKNEQEPEGCWFGRWG VNYIYGTWSVLVALEAIGESMRAPYIRKAVNWVKKVQNPDGGWGE >seq_ID 266 SPIWDTGIVLHSLVESGVSPDHEALLRSVSWLLAKEVTHEGDWKVKCPDAPVGGWYFEYANE FNPDCDDTAKVLMATSRFSSVDFPDAGRLRDARNRGLQWLLHMQNKDGGWAAFDKGCDNEL LTYIPFADHNAMIDPSTEDITGRVLETLAREGFDNTHPVVKRAIQYLHKTQDAEGPWYGRWGS NFIYGTWLVLQGLKAVGEDMTXPRYQRAANWLLNVQNXNGSWGE >seq_ID 323 SPMWDTSLAAHAFLESGDREDPRLIRALDWLVDKQILDHVGDWAVRRPGLRPGGWAFQYEN PDYPDVDDTAVVAMAMHRTDPERYAENIDRACEWLAGMQSKNGGWGAFDPENEHYYLNSIP FADHGALLDPPTVDVTARCIGCLAQVDAEAFADNIKRGIGFIKREQEPDGSWFGRWGANYIYGT WSALVALKGAGEDMSQPYIRKSVAWLKGRQGPDGGWGE >seq_ID 274 SPVWDTILSMQALLDTKEVFQPSPTLKKAMEWLLEQQVRAWGDWKVYVSDARGGGWAFQRA NSFYPDVDDTIMVMMALRNVSPRGESKVVDEAIERALFWVLGMQCEDGGWAAFDRDNAKAFL TKVPFADHNAMIDPSTADLTSRTFEMFAMIAPEVFTIHHPVVRRGLEFLKKDQCKDGSWFGRW GVNYMYGTWQVLRGLRLIGEDMSKGYVRKGVEWFKSVQLEDGGWGE >seq_ID 284 SPVWDTVAQLHALIASGLARRDEALRRAASWLLTRQSRTHGDWSGRNPAEPGGFYFEFRNEF YPDVDDTAMALMVLTQAEANVATDVQHAAIARALAWMLGMQNRDGGWAAFDRDNDKHFLTQ VPFADHNAMIDPSTADITGRVLGALSHVPSYGPDHPSVRRAIAFLQRDQEPDGSWYGRWGVN YLYGTGQVLRGLRAIGFDMQQPFVRRAARFLSAHQNDDGGWGE >seq_ID 285 SPVWDTAITIIALAESGLPKNHPAFEQAATWLEKKEIRFKGDWAVRMPGVEPSGWAFEHENKY YPDTDDTMMVLMALRHVQSRNSAERCEQFDRALKWLLAFQCQDGGWAAFDKDVTASWLEH VPFADHNAILDPTCSDLTARVLELLGSISFDRQSAIVRRAVAMMRRTQETDGSWYGRWGVNYI YGTWQALRGLAAIGENMDQEWIRRGRDWLESCQNDDGGWGE >seq_ID 308 SPVWDTAIAGYALGESGCAPQSALRRMADWLLTKEVRRKDDWSVKRPDVEPSGWYFEFANE FYPDTDDTAMVLLSLLHGRATNPAAQEACAKRAVNWLLAMQSKDGGWAAFDVDNDWKPLSY VPFADHNAMLDPSCPDITGRVLEALCKYGVSQEHPAVLRAIDYLIQTQEQDGSWHGRWGVNY VYGTFLALRGLKAAGVSDREAYVLRAGEWLDLIQNPDGGWGE >seq_ID 288 SPVWDTAITAVSLAESGLEPDHPALQKSAEWLLDKEVRIQGDWAIKNRHGEASGWAFEFNNEF YPDVDDTLKVLLALRLIKTRDEETKREAMERALGWVMSFQCSDGGWAAFDKDVTQRWLEDVP FADHNAILDPTCSDITARCLELLGKMGCTSDHPAVRRALRMVRETQEPDGTWWGRWGVNYIY GTWQILRGLSALKIDMNQDWIVRAKEWLESCQNPDGGWGE >seq_ID 287 SPVWDTAITSVALTSSGVKPDHPQIQKAADWLLDREVVMRGDWKVKNPYPHASGWAFEFNND FYPDADDTFKVLLALMKMKSSDPERQRKIMDRALDWARSFQCKDGGFAAFDKDVTKKWLEHV PFADHNAILDPSCSDITARGLECMGKLGWPRTDRVIRRAIRYLKKTQEEDGSWWGRWGVNYIY GTWQSLRGLEAIGEDMNQDWVVRARNWLESCQNPDGGWGE >seq_ID 289 SPIWDTAIVTMAIAESGQDPNDPRLQKAADWLLEREIGFRGDWRENCDFPEATGWAFEFNND WYPDVDDTFQVILGLKPLSASDSRRQEQTLDRAIRWCRAMQCREGGFAAFDKDINDAWLNEV PFADHNAILDPPCSDITGRALETLSLMGFDREDPVVRRARQYLMETQLEDGSWFGRWGVNYIY GTGHALRGLHAIGEDINGSAMQRARNWLENCQNDDGGWGE >seq_ID 286 SPVWDTAINVISLAESGLLSDHPALQKAADWLVNKEVRFRGDWSVNNSYPQVSGWAFEYNNV YYPDTDDTAMVLMALRLIRPKDPQALNELFRRALDWQLSFQCRDGGWAAFDKNVTTPWLEDM PFADHNAILDPTCSDLTARTLELLGYTGFDPKAQSVRDALQYLIDTQDEDGSWYGRWGVNYIY GTWQVLRGLRAMGQDMTQDWILRGRDWLESCQNSDGGWGE >seq_ID 270 SPVWDTALAMSALLEGDTAPDDEALQRGCRWLLGKEVRHRGDWQVNVGAEPGGWFFEYEN EFYPDCDDTAEVLAVLERVRLSDPEEDQRRRDALDRALAWQLGMQSTNGGWGAFDKDCDHR ILELVPFADHNAMIDPPTVDVTSRSIEAALAMGVPASDAAIRRAVRFLYSEQEADGSWYGRWG SNYLYGTWLALCALRSAGEDLTSPAVQRAVEWLLSVQQEDGGWGE >seq_ID 322 SPVWDTGIAAHALGEAGHASAMQSTADWLLTKEVRRKGDWSVKRPDVEPSGWYFEFANEFY PDIDDTAQVLLGLAHAKASDPAKQKACMDRAVAWLLAMQGSDGGWAAFDVDNNWEFLSSVP FADHNAMLDPTCPDITGRVLEALAACGVPNSHPAVKRGVEFLRNSVEKDGSWYGRWGVNYIY GTYLALRGLRASGEDDREAHILRAGEWLRAIQNADGGWGE >seq_ID 263 SPVWDTSLILNALLAGSEKTETDPKILKAGQWLLDREVREIGDWKIKNNRGPVGGWYFEYANE FYPDCDDTAEVITVLNQMQFSDPEKEKAKQVAQQRGLDWLLSMQNKDGGWPAFDKNCDKQS LTYMPFADHNAMIDPSYEDITGRTLEALASLGFSEDDPIVRRAVDFLKSKQLPDGTWYGRWGC NFLYGTWLAISGLYHAGEDLNEERYQSLLSWLEQCQNEDGGWGE >seq_ID 268 SPVWDTCLILNSMLEHLEPDHPRVQKAAEWLLSKEVTEPGDWQVKCPEAPVGGWYFEYANEF YPDCDDTAEVLAALQRVQFTDADREAQKRGAIQRGLGWLLAMQNQDGGXAAFDRECTREALT YVPFADHNAMIDPSNGDITGRVLKALDYAGYSPDDPIVRGGVDFLLANQEPDGTWYGRWGCN HLYGSWLVVWGLKHAGVNLQQTQFTQVMSWLESCQNADGGWGE >seq_ID 265 SPVWDTTNAMTAVLDAGLPGNHPAVLRAARWLLSKEVRMPGDWRLWYKNGEPGGWFFEYN NEFYPDADDTAEALHCLCRVVFDCEDEMDRCRAAIKRGLNWQFACQNPDGGWPAFDKECDD EYLTFIPFADHNAMIDPSCCDITGRSLQALSKLGYTTNDVDVKRAIDYLLDAQEDDGTWYGRWG INYIYGTWLAVQGLRAIGVDLSEKRFQKVTKWLRKKQNPDGGWGE >seq_ID 269 SPVWDTCLILNSLLEHLEPDHPRLQHAAEWLLSKEVTEPGDWQVKCPEAPIGGWYFEYANEFY PDCDDTAEVLAALQRVRFSDADREAQKHAAIERGLGWLLAMQNGDGGWAAFDRECTREALT YVPFADHNAMIDPSNGDITGRVLKALDYSGRSPQDPVVQGGVHFLLANQEPDGTWYGRWGC NHLYGSWLAIWGLKHAGVDSQQSQFMRLLSWLESCQNPDGGWGE >seq_ID 319 SPVWDTSLSAHALMEAGLEENDKRLEGLLDWLKDLQILDVKGDWVARRPDVRPGGWAFQYR NDHYPDVDDTAVVAMAMHRQGDEKYKEAIDRAAEWIVGMQSSSGGWGAFDPENEHFYLNSI PFADHGALLDPPTEDVTARCVGFLAQLDPDAYAEPIKRGVEFLKRTQQEDGSWWGRWGANF VYGTWSVLCALNAAGEDPKSPYIQKAVAWLKSRQREDGGWGE >seq_ID 321 SPVWDTGIACQALQEVGGPAADAGVQRALDWLVERQLRDEPGDWRRDRPDLEGGGWAFQY NNPHYPDLDDTSMVAWVMQVADHGRYREEIRRAAKWVVGMRSEGGGFASFEVDNTYYYLNH IPFADHGXLLDPPTXDVTARCIAVLAITDRAQHETVIREAIDFLFVDQEEDGSWFGRWGTDYIYG TWSVLSXLDVVGFDMRDARVRXSVEWLFXQQNPDGGWGE >seq_ID 272 SPVWDTGLVALALQEVDKHNSQDALQRNLKQAYSWLLSKQLKDEPGDWRISKPTLTGGGWAF QFNNPHYPDVDDTAVVAFALAQAEHTELDESIHLATRWIEGMQSQNGGYGAFDVDNTFYYLNE IPFADHGALLDPPTADVSARCAMLMARVAKDHEEYLPALERTIQYLRSEQEADGSWFGRWGT NYVYGTWSVLLGLEQTNVPKTDPLFTKAAQWLKSVQRPDGGWGE >seq_ID 273 SPVWDTGLVALALPEVDKHNSQDALQPNLKQAYSWLLSKQLKDQPGDWRISKPTLTGGGWAF QFNNPHYPDVHDTAVLAFALAQAEHTELDESIHLATRWIEGMQSQNGGYGAFDVDNTFYYLNE IPFADHGALLDPPTADVSARCAMLMARVAKGHEEYLPALERTIQYLRSEQEADGSWFGRWGT NYVYGTWSVLLGLEQTNVPKTDPLFTKAAQWLKSVQRPDGGWGE >seq_ID 317 SPVWDTILGMIGLVDCGHDGKDPLLVTARDWIVKRQLLVNYGDWKVYNPNGPSGGWSFEYDN SWYPDVDDTAAIVIGFLKQDYEFRHSEVVKRACDWIASMQNQXGGWAAFDINNDKTFLNEIPF SDMESLCDPSSPDVVGRVLEAFGILNDPKYAEVCRRGIEYLRRTQESEGSWFGRWGVNYVYG TSNVLCSLKRQDVAXKDPMVTRALTWLKKVQNKDGGWGE >seq_ID 215 MGRQTRNLTRREPAAEAEERGFRLLDAHRRADSSWVGELSSSALATAMSALALRLLGHPAES GPVAGGLAWLAATRNPDGGWGDAPGEPSNMNATSIAAAALARCAPRRYREEVAGGRRWVE EHGGFAALNDPRTTTLSGPGRTLWALAGLVPPERVRKLPTEMILLPRRIRRTVSTTFPAFLSLSL LHERFRFSPRWRRPLRRRAEREALAWLRRAQGPNGSYEESAFLTSLIAAALTAAGAEGGDIVR RALPFVLRSRRPDGSWPIDRDLENFDTTQAILAHHEAGRPLREAGRVREWLLDNQFRRPFFPT SSPPGGWAWAYPAGWPDTDDTACALRSLRLLGVPAGHPSIRLGLRWLYRMQNRDGSWPTFV RGSRMPFDHGCPYITSQVLSALALMGPEARRGAPLRRALAYLRRAQRPDGSLGSLWFRPHTR GTAAAVEAFSDLGLSGDPLVGRAARWLAEHQNPDGGWGDGHGAPSTAEETAWASAALLRLG GGEAARKGVRWLVEHQDPGGWKPAVIGLYYASLSYSDTFYALSYPLVALARHRRLSR >seq_ID 191 MIKKILVLILLMVVVTSKVDIERVQTVIRDAREICWNELTDNEWVYPTYLGTLFLSEYYFELKALGI QNSQFEESKFTQILLGSQLPDGSWVQVEDAYIQTGQLDATIFNYWYLKAVGIDIHTDTMKKAQE WIKANGGIEKAQTMTKFKLAMFGQYPWKKLFKIPLILFYKKFNPLYIKDITAQWVYPHMTALAYL QNQRIIFNVAVSISELYKNKAPKIKNHQKKGRPSFFINNLVQEMLKLRQPMGSFGGYTVSTLLSM LALNDYTGRTNKHKSEISDALKKGLDFVEFNYFNFRQAYHGSLDDGRWWDTILISWAMLESGE DKEKVRPIVENMLQKGVQPNGGIEYGYDFGYAPDADDTGLLLQVLSYYGTDYADAMDKGAEF VYSVQNTDGGFPAFDKGKMGKNPLYKYAFKIAGIADSAEIFDPSSPDVTAHILEGLISSDRSNYD VVVKSLKYFMDTQENFGSWEGRWGINYIYAAGAVLPALKKMNNGWAKAVNWLVSKQNADGG FGETTLSYRDPKKYNGIGVSTVTQTSWGLLGLLAVEDHYDVKEAIEKARDGEFKDISVVGTGHR GLLYLQYPSYARSFPVISLGRFLDQQR 

1-26. (canceled)
 27. An enzyme mutant with cyclase activity which comprises an amino acid sequence selected from the group consisting of the amino acid sequences of SEQ ID NO: 2 to 326 or a partial sequence thereof, wherein said enzyme mutant is a mutant of a wildtype enzyme and catalyzes at least the cyclization of a citronellal isomer to at least one isopulegol isomer.
 28. The enzyme mutant of claim 27, comprising; a) a mutation in position F486 of the amino acid sequence of SEQ ID NO: 2; or b) a mutation in a sequence selected from the group consisting of the amino acid sequences of SEQ ID NO: 3 to 326, wherein the mutated position corresponds to position F486 of the amino acid sequence of SEQ ID NO:
 2. 29. The enzyme mutant of claim 27, wherein up to 25% of the amino acid residues in each amino acid sequence are altered relative to SEQ ID NO: 2 to 326 by deletion, insertion, substitution, addition, inversion, or a combination thereof.
 30. The enzyme mutant of claim 28, wherein the mutation in position F486 of the amino acids sequence of SEQ ID NO: 2, or in a position corresponding to this position in one of the amino acid sequences of SEQ ID NO: 3 to 326, is a substitution selected from the group consisting of F486N, F486Q, F486L, F486M, F486E, F486G, F486S, F486V, F486T, F486C, F486I and F486A.
 31. The enzyme mutant of claim 28, wherein additionally there is at least one mutation in one of the positions W374, D437, D440, F428, W555, Y561, Y702, Y705 of the amino acid sequence of SEQ ID NO: 2 or in at least one corresponding position selected from these positions in one of the amino acid sequences of SEQ ID NO: 3 to
 326. 32. The enzyme mutant of claim 27, wherein there is no mutation in position D437 and/or D439 and/or D440 of the amino acid sequence of SEQ ID NO: 2 or the respective corresponding position in one of the amino acid sequences of SEQ ID NO: 3 to
 326. 33. The enzyme mutant of claim 27, wherein there is no mutation in position Y702 of the amino acid sequence of SEQ ID NO: 2 or in the corresponding position in one of the amino acid sequences of SEQ ID NO: 3 to 326, or if a mutation is present, it is a Y702F substitution or a corresponding substitution.
 34. The enzyme mutant of claim 28, which is optionally further mutated in at least one of positions P229, D439, D508, E601, G553, G556, N432, P436, P499, R224, 5371, T376, T563, W414, or W624 of the amino acid sequence of SEQ ID NO: 2 or in at least one corresponding position selected from these positions in one of the amino acid sequences of SEQ ID NO: 3 to
 326. 35. The enzyme mutant of claim 27, comprising: a) a single mutant selected from the group consisting of i) F486X, with X═N, Q, L, M, E, G, S, V, T, C, I, or A of the amino acid sequence of SEQ ID NO: 2; ii) Y702X, with X═F, A, C, or S of the amino acid sequence of SEQ ID NO: 2; and iii) Y561X, with X=A or S of the amino acid sequence of SEQ ID NO: 2; b) a multiple mutant comprising F486A/Y702A, F486A/Y561A, or F486A/Y705A of the amino acid sequence of SEQ ID NO: 2; and c) a mutant corresponding to a) or b), derived from one of the amino acid sequences of SEQ ID NO: 3 to
 325. 36. The enzyme mutant of claim 27, which displays at least 50% of the citronellal-isopulegol cyclase activity of an enzyme that comprises the amino acid sequence of SEQ ID NO: 2 from position 1 to 725, from position 2 to 725, or from position 16 to 725, and optionally N-terminally extended with a methionine residue.
 37. The enzyme mutant of claim 36, wherein the citronellal-isopulegol cyclase activity is determined using a citronellal as a reference substrate under standard conditions.
 38. The enzyme mutant of claim 27, wherein the mutation takes place in an enzyme that comprises the amino acid sequence of SEQ ID NO: 2 from position 1 to 725, from position 2 to 725, or from position 16 to 725, optionally extended N-terminally with a methionine residue.
 39. A nucleic acid sequence encoding the mutant of claim
 27. 40. An expression cassette comprising the nucleic acid sequence of claim
 39. 41. A recombinant vector comprising, under the control of at least one regulatory element, at least one nucleic acid sequence of claim 39 or at least one expression cassette comprising said at least one nucleic acid sequence.
 42. A recombinant microorganism, comprising: a) at least one nucleic acid sequence of claim 39; b) at least one expression cassette comprising said at least one nucleic acid sequence; or c) at least one vector comprising, under the control of at least one regulatory element, said at least one nucleic acid sequence or said at least one expression cassette.
 43. A method of production of isopulegol of general formula (I)

comprising cyclizing citronellal of general formula (II)

to isopulegol of formula (I) by means of an enzyme of EC class EC 5.4.99 or EC class EC 5.4.99.17, or in the presence of a microorganism expressing said enzyme.
 44. A method of production of isopulegol of general formula (I)

comprising cyclizing citronellal of general formula (II)

to isopulegol of formula (I) by means of the enzyme mutant of claim 27, or in the presence of a microorganism expressing said enzyme mutant.
 45. A method of production of menthol of formula III

comprising a) cyclizing citronellal to isopulegol by the method of claim 43; and b) catalytically hydrogenating isopulegol to menthol.
 46. The method of claim 45, where the hydrogenation takes place in the presence of hydrogen and a catalyst comprising: a) 30% to 70% by weight of oxygen-containing compounds of nickel, calculated as NiO; b) 15% to 45% by weight of oxygen-containing compounds of zirconium, calculated as ZrO₂; c) 5% to 30% by weight of oxygen-containing compounds of copper, calculated as CuO; and d) 0.1% to 10% by weight of oxygen-containing compounds of molybdenum, calculated as MoO₃, wherein the % by weight is based on the dry, unreduced catalyst.
 47. A method for enzymatic or biocatalytic conversions of compounds of general formula IV

in which “a”, “b”, “c” and “d”, in each case independently of one another, represent a single or double C—C bond, with the proviso that cumulative double bonds are excluded; and with the following provisos: R₁ is defined as: (1) when “a” is a double bond: R₁ is selected from the group consisting of: oxo (═O), and CH—(CH₂)_(n)—Z,  in which n is 0, 1 or 2 and  Z is OH, CHO; C(O)C₁-C₄-alkyl; COOH, C(CH₂)—CH═CH₂;  C(OH)(CH₃)—CH═CH₂; C(CH₃)═CH—CH═CH₂; or a radical of the formula C(CH₃)═CH—CH₂Y  in which  Y is OH, CH₂OH, COOH, or CH₂C(O)CH₃; or (2) when “a” is a single bond: R₁ is selected from the group consisting of: CH₃; CHO; CH₂CH₂OH; CH═CH₂; CH₂C(O)OH; CH₂CHO; and C₃H₆CH(CH₃)CHO; and, when “a” is a double bond, it has E or Z configuration; R₂ and R₃ are defined as: (1) when “a” and “b” are each a single bond: R₂ and R₃ independently of one another are H, C₁-C₄-alkyl, or OH, or R₂ and R₃ together are a methylene (═CH₂) or oxo (═O) group; or (2) when “a” or “b” is a double bond, one of the radicals R₂ and R₃ is absent and the other of the two radicals is H, C₁-C₄-alkyl, or OH; R₄ is H or hydroxy-C₁-C₄-alkyl; R₅ and R₆ are defined as: (1) when “c” is a single bond: R₅ and R₆ are each H, or R₅ and R₆ together are an oxo (═O) group; or (2) when “c” is a double bond, one of the radicals R₅ and R₆ is absent and the other of the two radicals is H; R₇, R₈, and R₉ are defined as: (1) when “d” is a single bond: two of the radicals R₇, R₈ and R₉ in each case independently of one another are H or C₁-C₄-alkyl, and the other of the radicals is OH; or (2) when “d” is a double bond, one of the radicals R₇, R₈ and R₉ is absent and the other of the two radicals in each case independently of one another are H or C₁-C₄-alkyl; R₁₀ is H or hydroxy-C₁-C₆-alkyl or mono- or polyunsaturated C₂-C₆-alkenyl; comprising reacting a compound of the formula IV in stereoisomerically pure form, or a stereoisomer mixture thereof: a) using an enzyme of class EC 5.4.99 or class EC 5.4.99.17, or the enzyme mutant of claim 27; or b) in the presence of a microorganism expressing said enzymes or enzyme mutant, wherein the microorganism comprises: i) at least one nucleic acid sequence coding for said enzyme mutant; ii) at least one expression cassette comprising said at least one nucleic acid sequence; or iii) at least one vector comprising, under the control of at least one regulatory element, said at least one nucleic acid sequence or said at least one expression cassette.
 48. The method of claim 47, comprising converting a compound selected from the group consisting of: a) compounds of formula IVa

in which R₁ i) is defined as: (1) when “a” is a double bond: R₁ is selected from oxo (═O), or CH—(CH₂)_(n)—Z,  in which n is 0, 1 or 2 and  Z is OH, CHO, C(O)C₁-C₄-alkyl; COOH, C(CH₂)—CH═CH₂;  C(OH)(CH₃)—CH═CH₂; C(CH₃)═CH—CH═CH₂; or a radical of the formula C(CH₃)═CH—CH₂Y  in which  Y is OH, CH₂OH, COOH, or CH₂C(O)CH₃; or (2) when “a” is a single bond: R₁ is selected from CH₃; CHO; CH₂CH₂OH; CH═CH₂; CH₂C(O)OH; CH₂CHO or C₃H₆CH(CH₃)CHO; and, when “a” is a double bond, it has E or Z configuration; or ii) is a radical of the formula CH—(CH₂)_(n)—Z in which n=0 and Z═CHO or COOH; n=1 and Z═OH; or n=2 and Z═C(O)CH₃; COOH, C(CH₂)—CH═CH₂; C(CH₃)═CH—CH═CH₂; iii) is a radical of the formula C(CH₃)═CH—CH₂Y in which Y is OH, CH₂OH, COOH, or CH₂C(O)CH₃; and “a” optionally has E or Z configuration; b) compounds of formula IVb

in which R₁ is defined as above or is CH₂CHO; and c) compounds of formula IVc

in which R₁ is defined as above, or is CH—CHO; and one of the radicals R₇ and R₈ is H and the other is C₁-C₄-alkyl, or wherein R₇ is ethyl and the double bonds “a” and “d” have Z configuration.
 49. The method of claim 47, in which the compound of formula IV is selected from citronellal, citral, farnesol, homofarnesol, homofarnesol derivatives, homofarnesylic acid, geranylacetone, melonal, nonadienal, and trimethyldecatetraene.
 50. A method for the cyclization of terpenes, the conversion of citronellal to isopulegol, or the conversion of compounds of the general formula IV, comprising utilizing an enzyme from EC class EC 5.4.99 or EC class EC 5.4.99.17.
 51. The method of claim 47 for the cyclization of terpenes and/or terpenoids, and for the conversion of compounds of the general formula IV, comprising utilizing: (a) the enzyme mutant of claim 27; (b) a nucleic acid coding for said enzyme mutant; (c) an expression construct comprising said nucleic acid; (d) a recombinant vector comprising, under the control of at least one regulatory element, at least one of the nucleic acid of (b) or at least one of the expression construct of (c); or (e) a recombinant microorganism comprising the nucleic acid of (b), the expression construct of (c), or the recombinant vector of (d).
 52. The method of claim 51 for the conversion of citronellal to isopulegol, or for the conversion of squalene to hopene. 